RU2811524C1 - Method for determining thickness of weathering crust of pre-jurassic complex using seismic data - Google Patents

Abstract

FIELD: geophysical exploration and interpretation of seismic data.

SUBSTANCE: invention is related, in particular, to determining the thickness of the weathering crust of the pre-Jurassic complex from seismic data. A method for determining the thickness of the weathering crust of the pre-Jurassic complex is proposed, in which, based on well data, the elastic and density properties of the weathering crust of the pre-Jurassic complex and the roof of Paleozoic rocks are determined; the convergence of the properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks are determined. In the absence of convergence of elastic and/or density properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks, based on seismic data, the presence of coal-bearing strata at the top of the pre-Jurassic complex is determined. In the presence of coal-bearing strata at the top of the pre-Jurassic complex and when the phase of the weathering crust of the pre-Jurassic complex is separated, the thickness of the weathering crust of the pre-Jurassic complex is determined based on seismic data by subtracting the seismic reflecting boundary of the top of the weathering crust from the seismic reflecting boundary of the base of the weathering crust. A method for developing the weathering crust of the pre-Jurassic complex based on a certain thickness of the weathering crust of the pre-Jurassic complex, a system for determining the thickness of the weathering crust of the pre-Jurassic complex and a machine-readable medium for determining the thickness of the weathering crust of the pre-Jurassic complex are also proposed.

EFFECT: increase in the accuracy of determining the thickness of the weathering crust of the pre-Jurassic complex using seismic data, an increase in the volume of extracted hydrocarbon fluid due to the development of the thickness of the weathering crust of the pre-Jurassic complex.

22 cl, 10 dwg

Description

The invention relates to the field of geophysical exploration and interpretation of seismic data, in particular, to determining the thickness of the weathering crust of the pre-Jurassic complex from seismic data.

One of the important search objects for the pre-Jurassic complex of Western Siberia is the weathering crust (CR). Predicting the regular structure of the weathering crust is a complex and ambiguous task, since its distribution depends on a complex of climatic, tectonic and other factors. It is known that, based on their structure, residual undisplaced weathering crusts are distinguished from redeposited ones; based on the type of distribution, they can be linear or areal. The variety of factors in the formation of the weathering crust determines their heterogeneous and extremely variable lithological composition vertically and laterally, as well as the variability in the thickness of the weathering crust from complete absence to tens of meters.

Most often, the weathering crust is most fully studied based on geophysical surveys of wells (GIS) and core. At the same time, difficulties arise when predicting the distribution of the weathering crust over the area, which is mainly due to the fact that the weathering crust has a different material composition and variable thickness. It should also be taken into account that the wells from which information on the weathering crust was obtained, as a rule, are located on local uplifts of the roof surface of the Paleozoic complex, where the revealed thickness of the HF does not exceed, on average, a few tens of meters. At the same time, in the submerged parts, an increased thickness of these deposits is predicted.

The study of the weathering crust was carried out on the basis of data from wells drilled in the Tomsk region. In this area, the bedrock Paleozoic deposits are represented predominantly by carbonate rocks, partly by igneous rocks and, to a lesser extent, by clayey-siliceous metamorphic rocks. The weathering crust is diverse in composition; within the study area, various lithotypes are distinguished: clayey rocks, siliceous, clayey-siliceous, siderite-clayey, siderite-siliceous, clayey-siliceous-siderite, clayey-siliceous-carbonate, bauxite-bearing rocks, breccias and chapterite- sandstones. The thickness of the weathering crust in the wells varies from 0 to 100 meters.

A method for seismic analysis of hydrocarbon systems is known from the prior art according to patent RU 2573166 (publication date: 01/20/2016, IPC G01V 1/28, E21B 43/00). A computer-implemented method according to patent RU 2573166 for analyzing a volume of data composed of voxels of seismic data, which displays an underground area, for the presence of a hydrocarbon system or a specific oil and gas complex of rocks, containing the following operations: dividing the volume of seismic data, forming many segments; and rank this set of segments according to the presence of a hydrocarbon system or a specific oil and gas complex of rocks; Moreover, this quantitative assessment of prospects is based on the calculation of at least two characteristics related to various elements of the hydrocarbon system or a specific oil and gas complex of rocks.

The common features of the known method with the claimed invention is the provision of interpretation of seismic data.

Taking into account the fact that the known method is used to determine the presence of a hydrocarbon system or a specific oil and gas complex of rocks using seismic data, the disadvantage of the known solution is the impossibility of using this method to determine the thickness of the weathering crust of the pre-Jurassic complex using seismic data.

The prior art knows a method for determining the elastic properties of rocks based on layer adaptive inversion of seismic data according to patent RU 2526794 (publication date: 08/27/2015, IPC: G01V 1/28). The method for determining the elastic properties of rocks based on reservoir adaptive inversion of seismic data is characterized by the use of reservoir models of the environment, in which the minimum temporary thickness of the layers corresponds to the real resolution of seismic exploration and sedimentation geology, and the corrected geoacoustic model of the impedances of the corresponding well, or the impedance trace, is used as the initial model a previously obtained seismoacoustic section along a secant profile; and when constructing a working model, the seismic time section is converted into a detailed layer model of acoustic impedances (seismoacoustic section), which indicates the ranges of changes in the acoustic parameters of the layers.

The common features are the study of the elastic properties of rocks in order to identify the range of changes in the acoustic parameters of the layers.

However, the known method according to patent RU 2526794 does not make it possible to determine with the required accuracy the presence of the weathering crust of the pre-Jurassic complex from seismic data and determine its thickness.

Since the weathering crust is characterized by a highly variable thickness of sediments, to implement the method it is also necessary to determine at what values of its thickness an independent reflection will be formed, without the effect of interference with the reflection from the roof of the bedrock Paleozoic. In addition, due to the fact that the thickness of the weathering crust often does not exceed the limit of the vertical resolution of the seismic record, the problem of determining the possibility of predicting changes in the weathering crust in the region of small thicknesses must be additionally solved.

The technical result of the claimed invention is to increase the accuracy of determining the thickness of the weathering crust of the pre-Jurassic complex using seismic data, increasing the volume of extracted hydrocarbon fluid due to the development of the thickness of the weathering crust of the pre-Jurassic complex.

The technical result is achieved due to the fact that a method is implemented for determining the thickness of the weathering crust of the pre-Jurassic complex, in which: on the basis of well data, the elastic and density properties of the weathering crust of the pre-Jurassic complex and the roof of Paleozoic rocks are determined; determine the convergence of the properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks; in the absence of convergence of elastic and/or density properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks, based on seismic data, the presence of coal-bearing strata at the roof of the pre-Jurassic complex is determined; in the presence of coal-bearing strata at the top of the pre-Jurassic complex and when separating the phase of the weathering crust of the pre-Jurassic complex on seismic data, the thickness of the weathering crust of the pre-Jurassic complex is determined by subtracting the seismic reflecting boundary of the top of the weathering crust from the seismic reflecting boundary of the base of the weathering crust.

The technical result is achieved due to the fact that a method is implemented for determining the thickness of the weathering crust of the pre-Jurassic complex, in which: on the basis of well data, the elastic and density properties of the weathering crust of the pre-Jurassic complex and the roof of Paleozoic rocks are determined; determine the convergence of the properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks; in the absence of convergence of elastic and/or density properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks, based on seismic data, the presence of coal-bearing strata at the roof of the pre-Jurassic complex is determined; in the absence of coal-bearing strata at the top of the pre-Jurassic complex, with the same composition of the Paleozoic bedrock at the deposit site and in the absence of separation of the phase of the weathering crust of the pre-Jurassic complex, the thickness of the weathering crust of the pre-Jurassic complex is determined on seismic data using root-mean-square amplitudes.

The technical result is achieved due to the fact that a method is implemented for determining the thickness of the weathering crust of the pre-Jurassic complex, in which: on the basis of well data, the elastic and density properties of the weathering crust of the pre-Jurassic complex and the roof of Paleozoic rocks are determined; determine the convergence of the properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks; in the absence of convergence of elastic and/or density properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks, based on seismic data, the presence of coal-bearing strata at the roof of the pre-Jurassic complex is determined; in the presence of coal-bearing strata at the top of the pre-Jurassic complex and when separating the phase of the weathering crust of the pre-Jurassic complex, the thickness of the weathering crust of the pre-Jurassic complex is determined on seismic data by subtracting from the seismic reflecting boundary of the base of the weathering crust the seismic reflecting boundary of the roof of the weathering crust, and also in the absence of coal-bearing strata at the top of the pre-Jurassic complex, with the same composition of the Paleozoic bedrock at the deposit site and in the absence of separation of the phase of the weathering crust of the pre-Jurassic complex, the thickness of the weathering crust of the pre-Jurassic complex is determined on seismic data using root-mean-square amplitudes.

The claimed method ensures the accuracy of determining the weathering crust in the inter-well space due, first of all, to the use of seismic data as the most correct tool for analyzing areas not illuminated by wells, and secondly, due to the use of well data, as well as through processing data on the absence or the presence of coal-bearing strata and their influence on the accuracy of determining the thickness of the weathering crust, as a result of obtaining the exact structure of the rock plates, more efficient development of the oil field is ensured and an increase in the volume of produced fluid.

The technical result is achieved due to the fact that a method is implemented for developing the weathering crust of the pre-Jurassic complex, in which:

- based on well data, the elastic and density properties of the weathering crust of the pre-Jurassic complex and the roof of Paleozoic rocks are determined;

- determine the convergence of the properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks;

- in the absence of convergence of elastic and/or density properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks, based on seismic data, the presence of coal-bearing strata at the roof of the pre-Jurassic complex is determined;

- in the presence of coal-bearing strata at the roof of the pre-Jurassic complex and when separating the phase of the weathering crust of the pre-Jurassic complex, the thickness of the weathering crust of the pre-Jurassic complex is determined on seismic data by subtracting the seismic reflecting boundary of the roof of the weathering crust from the seismic reflecting boundary of the base of the weathering crust;

- constructing a well along the thickness of the weathering crust of the pre-Jurassic complex.

The technical result is achieved due to the fact that a method is implemented for developing the weathering crust of the pre-Jurassic complex, in which:

- based on well data, the elastic and density properties of the weathering crust of the pre-Jurassic complex and the roof of Paleozoic rocks are determined;

- determine the convergence of the properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks;

- in the absence of convergence of elastic and/or density properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks, based on seismic data, the presence of coal-bearing strata at the roof of the pre-Jurassic complex is determined;

- in the absence of coal-bearing strata at the top of the pre-Jurassic complex, with the same composition of the Paleozoic bedrock at the deposit site and in the absence of separation of the phase of the weathering crust of the pre-Jurassic complex, the thickness of the weathering crust of the pre-Jurassic complex is additionally determined on seismic data using root-mean-square amplitudes;

- constructing a well along the thickness of the weathering crust of the pre-Jurassic complex.

The technical result is achieved due to the fact that a method is implemented for developing the weathering crust of the pre-Jurassic complex, in which:

- based on well data, the elastic and density properties of the weathering crust of the pre-Jurassic complex and the roof of Paleozoic rocks are determined;

- determine the convergence of the properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks;

- in the absence of convergence of elastic and/or density properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks, based on seismic data, the presence of coal-bearing strata at the roof of the pre-Jurassic complex is determined;

- in the presence of coal-bearing strata at the roof of the pre-Jurassic complex and when separating the phase of the weathering crust of the pre-Jurassic complex, the thickness of the weathering crust of the pre-Jurassic complex is determined on seismic data by subtracting the seismic reflecting boundary of the roof of the weathering crust from the seismic reflecting boundary of the base of the weathering crust,

and also in the absence of coal-bearing strata at the top of the pre-Jurassic complex, with the same composition of the Paleozoic bedrock at the deposit site and in the absence of separation of the phase of the weathering crust of the pre-Jurassic complex on seismic data, the thickness of the weathering crust of the pre-Jurassic complex is additionally determined using root-mean-square amplitudes;

- constructing a well along the thickness of the weathering crust of the pre-Jurassic complex.

The technical result is achieved due to the fact that systems for determining the thickness of the weathering crust of the pre-Jurassic complex are implemented, including at least one processor, RAM and machine-readable instructions for executing the stated methods for determining the thickness of the weathering crust of the pre-Jurassic complex.

The technical result is achieved due to the fact that machine-readable media are used to determine the thickness of the weathering crust of the pre-Jurassic complex, containing machine instructions for the claimed methods for determining the thickness of the weathering crust of the pre-Jurassic complex.

There is an option for implementing methods, systems and machine-readable media for determining the thickness of the weathering crust of the pre-Jurassic complex, in which the well data is acoustic and density logging.

There is an option for implementing methods, systems and machine-readable media for determining the thickness of the weathering crust of the pre-Jurassic complex, in which convergence is understood as the coincidence of the elastic and/or density properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks of more than 60%.

There is an option for implementing methods, systems and machine-readable media for determining the thickness of the weathering crust of the pre-Jurassic complex, in which, in the case of convergence of the elastic properties of the weathering crust and the roof of Paleozoic rocks, the absence of traceability of the weathering crust from seismic data is accepted.

There is an option for implementing methods, systems and machine-readable media for determining the thickness of the weathering crust of the pre-Jurassic complex, in which the absence of a coal-bearing layer is accepted if its thickness is less than 10 m.

There is an option for implementing methods, systems and machine-readable media for determining the thickness of the weathering crust of the pre-Jurassic complex, in which, additionally, using seismic data, a map of coal-bearing strata is constructed, on the basis of which the presence of coal-bearing strata at the roof of the pre-Jurassic complex is determined.

There is an option for implementing methods, systems and machine-readable media for determining the thickness of the weathering crust of the pre-Jurassic complex, in which the separation of the phase of the weathering crust of the pre-Jurassic complex is accepted when the thickness of the weathering crust of the pre-Jurassic complex is 60 meters or more.

There is an option for implementing methods, systems and machine-readable media for determining the thickness of the weathering crust of the pre-Jurassic complex, in which, based on root-mean-square amplitudes, a map of root-mean-square amplitudes is constructed and the thickness of the weathering crust of the pre-Jurassic complex is determined.

There is an option for implementing methods, systems and machine-readable media for determining the thickness of the weathering crust of the pre-Jurassic complex, in which, when determining the composition of the Paleozoic bedrock at the deposit site, the deposit is divided into areas of no more than 30 km ² .

There is an option for implementing methods, systems and machine-readable media for determining the thickness of the weathering crust of the pre-Jurassic complex, in which the composition of the Paleozoic bedrock is determined as a result of the analysis of core material, interpretation of logging curves (GIS) and integration of these data in the field.

There is an option for implementing methods, systems and machine-readable media for determining the thickness of the weathering crust of the pre-Jurassic complex, in which the composition of the Paleozoic bedrock is determined as a result of gravitational, magnetic and electromagnetic measurements of the deposit.

The invention is illustrated by the following figures.

Fig. 1 – acoustic and density logging data in the area near well No. 1 (well 1).

Fig. 2 – comparison of the convergence of acoustic logging of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks.

Fig. 3 - comparison of the convergence of density logging of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks.

Fig. 4 – example of seismic data in the area near well No. 1 (well 1).

Fig. 5 – map of the presence of coal-bearing strata in the field.

Fig. 6 – scheme for obtaining a map of the thickness (thickness) of the weathering crust in the presence of coal-bearing strata at the roof of the pre-Jurassic complex and when dividing the phase of the weathering crust of the pre-Jurassic complex using seismic data.

Fig. 7 – map of the composition of bedrock Paleozoic rocks.

Fig. 8 – map of root-mean-square amplitudes.

Fig. 9 – regression dependence of the thickness (thickness) of the weathering crust according to well data on the root-mean-square amplitude data.

Fig. 10 – map of the predicted (determined using the method) thickness of the weathering crust using root-mean-square amplitudes.

When implementing a method for determining the thickness of the weathering crust of the pre-Jurassic complex, the following is carried out.

Based on well data (Fig. 1), the elastic and density properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks are determined. In fig. Figure 1 shows an example of acoustic logging (left), which is used to determine the elastic properties of the weathering crust of the pre-Jurassic complex and the roof of Paleozoic rocks, and also an example of density logging (right), which is used to determine the density properties of the weathering crust of the pre-Jurassic complex and the roof of Paleozoic rocks.

Next, the convergence of the properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks is determined (Fig. 2, 3). Figure 2 shows an example of a comparison of the elastic properties of the weathering crust of the pre-Jurassic complex and the roof of Paleozoic rocks. In fig. Figure 3 shows an example of a comparison of the density properties of the weathering crust of the pre-Jurassic complex and the roof of Paleozoic rocks. In fig. 2, 3 it is clear that the convergence is about 50%. This value allows us to conclude that there is no convergence of the elastic and density properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks.

The most contrasting division between the weathering crust and Paleozoic rocks in terms of elastic properties is observed in groups of rocks represented by pure carbonates and carbonates with inclusions of basic volcanics. Paleozoic rocks in these groups are characterized by increased values of velocities and densities relative to both the overlying Jurassic deposits and deposits of the weathering crust. There is a separation, but less contrasting (about 50% convergence), in the group of rocks represented by acidic effusives: the acoustic impedance of the Paleozoic complex has velocities and densities lower than in the previous group of rocks. For carbonate-siliceous and metamorphic (schist) rock groups, the values of longitudinal wave velocities and density in the bedrock Paleozoic are lower than in other groups, but nevertheless differ from the elastic properties of the overlying rocks: both Lower Jurassic sediments and the weathering crust.

Thus, the difference in the elastic properties of the weathering crust and the Paleozoic bedrock plays an important role in the analysis. In the case where similarity in the elastic properties of the weathering crust and the Paleozoic bedrock is observed, then no contrast is formed at the sediment boundary, and the elastic properties change quite smoothly along the section.

In the absence of convergence of elastic and/or density properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks, the presence of coal-bearing strata at the top of the pre-Jurassic complex is determined on the basis of seismic data.

In fig. Figure 4 shows a seismic section of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks. Seismic data shows the presence of a coal-bearing layer - the upper dotted line is pink.

In fig. Figure 5 shows a map of the presence of coal-bearing strata (coals) in the deposit area. The presence of coals more than 10 meters thick makes it possible in the future to more accurately determine the thickness of the weathering crust of the pre-Jurassic complex. Based on comparison with well data, the interval from 0 to approximately 10 meters remains blind for the wave field due to the limitation of seismic resolution. Therefore, areas identified as a complete absence of coal-bearing strata must be assessed in this interval, where the thickness of the coals ranges from 0 to 10 meters. Since coal seams have greatly reduced elastic properties, it is possible to additionally use the inversion results, namely acoustic impedance, to predict the distribution of the coal strata of interest. Thus, additionally using AVO analysis methods and the results of inversion transformations, it is possible to obtain a more accurate predictive map of the distribution of coal seams in the terrigenous section.

In the presence of coal-bearing strata at the roof of the pre-Jurassic complex and when separating the phase of the weathering crust of the pre-Jurassic complex on seismic data (Fig. 4), the thickness of the weathering crust of the pre-Jurassic complex is determined by subtracting the seismic reflecting boundary of the roof of the weathering crust from the seismic reflecting boundary of the base of the weathering crust (Fig. 6) .

In fig. 4 to the right relative to well No. 1, a phase separation of the weathering crust is observed. This indicates that in this area the thickness of the weathering crust exceeds 60 m. In this case, no other additional data is required to accurately determine the thickness of the weathering crust of the pre-Jurassic complex. The thickness of the weathering crust can be accurately determined by subtracting the seismic reflector of the top of the weathering crust from the seismic reflector of the base of the weathering crust (Fig. 6).

In the absence of coal-bearing strata at the top of the pre-Jurassic complex, with the same composition of the bedrock Paleozoic and in the absence of separation of the phase of the weathering crust of the pre-Jurassic complex, the thickness of the weathering crust of the pre-Jurassic complex is additionally determined on seismic data using root-mean-square amplitudes.

In the presence of coal-bearing strata, but in the absence of phase separation from the roof of the weathering crust, i.e. when the thickness of the HF is less than 60 meters, it is necessary to use a map of root-mean-square amplitudes: if well data is available, look for regression dependencies of the thickness of the weathering crust according to well data and values from the amplitude map; in the absence of well data, it is necessary to use the amplitude map for assessment at a qualitative level - an increase in the reflection intensity characterizes decrease in the thickness of the weathering crust.

In fig. Figure 7 shows an example of a map of the composition of bedrock Paleozoic rocks (Paleozoic rocks). This map can be constructed by any known methods, for example, as a result of analysis of core material, interpretation of logging curves (GIS) and integration of this data in the field; or, for example, as a result of gravitational, magnetic and electromagnetic measurements of the deposit. The thickness of the weathering crust of interest is located in an area of the deposit with a homogeneous composition of the Paleozoic bedrock, consisting of felsic effusives and mafic effusives. Additionally, for this section we obtain a map of root-mean-square amplitudes (Fig. 8). Thus, using data on root-mean-square amplitudes for a given area, we can also obtain accurate values of the thickness of the weathering crust of the pre-Jurassic complex, presented, for example, in the form of a map.

A complete map of the thickness of the weathering crust of the pre-Jurassic complex is shown in Fig. 10.

In accordance with the above-described methods for determining the thickness of the weathering crust of the pre-Jurassic complex, an increase in the accuracy of determining the thickness of the weathering crust of the pre-Jurassic complex using seismic data is ensured, as well as an increase in the volume of extracted hydrocarbon fluid due to the development of the thickness of the weathering crust of the pre-Jurassic complex.

Claims (51)

1. A method for determining the thickness of the weathering crust of the pre-Jurassic complex, in which: - based on well data, the elastic and density properties of the weathering crust of the pre-Jurassic complex and the roof of Paleozoic rocks are determined; - determine the convergence of the properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks; - in the absence of convergence of elastic and/or density properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks, based on seismic data, the presence of coal-bearing strata at the roof of the pre-Jurassic complex is determined; - in the presence of coal-bearing strata at the roof of the pre-Jurassic complex and when separating the phase of the weathering crust of the pre-Jurassic complex, the thickness of the weathering crust of the pre-Jurassic complex is determined on seismic data by subtracting the seismic reflecting boundary of the roof of the weathering crust from the seismic reflecting boundary of the base of the weathering crust. 2. A method for determining the thickness of the weathering crust of the pre-Jurassic complex, in which: - based on well data, the elastic and density properties of the weathering crust of the pre-Jurassic complex and the roof of Paleozoic rocks are determined; - determine the convergence of the properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks; - in the absence of convergence of elastic and/or density properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks, based on seismic data, the presence of coal-bearing strata at the roof of the pre-Jurassic complex is determined; - in the absence of coal-bearing strata at the top of the pre-Jurassic complex, with the same composition of the Paleozoic bedrock at the deposit site and in the absence of separation of the phase of the weathering crust of the pre-Jurassic complex, the thickness of the weathering crust of the pre-Jurassic complex is determined on seismic data using root-mean-square amplitudes. 3. A method for determining the thickness of the weathering crust of the pre-Jurassic complex, in which: - based on well data, the elastic and density properties of the weathering crust of the pre-Jurassic complex and the roof of Paleozoic rocks are determined; - determine the convergence of the properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks; - in the absence of convergence of elastic and/or density properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks, based on seismic data, the presence of coal-bearing strata at the roof of the pre-Jurassic complex is determined; - in the presence of coal-bearing strata at the roof of the pre-Jurassic complex and when separating the phase of the weathering crust of the pre-Jurassic complex, the thickness of the weathering crust of the pre-Jurassic complex is determined on seismic data by subtracting the seismic reflecting boundary of the roof of the weathering crust from the seismic reflecting boundary of the base of the weathering crust, and also in the absence of coal-bearing strata at the top of the pre-Jurassic complex, with the same composition of the Paleozoic bedrock at the deposit site and in the absence of separation of the phase of the weathering crust of the pre-Jurassic complex, the thickness of the weathering crust of the pre-Jurassic complex is determined on seismic data using root-mean-square amplitudes. 4. A method for determining the thickness of the weathering crust of the pre-Jurassic complex according to claims 1-3, in which the well data is acoustic and density logging. 5. A method for determining the thickness of the weathering crust of the pre-Jurassic complex according to claims 1-3, in which convergence is understood as the coincidence of the elastic and/or density properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks of more than 60%. 6. The method for determining the thickness of the weathering crust of the pre-Jurassic complex according to claims 1-3, in which, in the case of convergence of the elastic properties of the weathering crust and the roof of the Paleozoic rocks, the absence of traceability of the weathering crust from seismic data is assumed. 7. A method for determining the thickness of the weathering crust of the pre-Jurassic complex according to claims 2-3, in which the absence of a coal-bearing layer is accepted if its thickness is less than 10 m. 8. A method for determining the thickness of the weathering crust of the pre-Jurassic complex according to claims 1-3, in which, additionally, based on seismic data, a map of coal-bearing strata is constructed, on the basis of which the presence of coal-bearing strata at the roof of the pre-Jurassic complex is determined. 9. The method for determining the thickness of the weathering crust of the pre-Jurassic complex according to claims 1-3, in which the separation of the phase of the weathering crust of the pre-Jurassic complex is taken when the thickness of the weathering crust of the pre-Jurassic complex is 60 meters or more. 10. Method for determining the thickness of the weathering crust of the pre-Jurassic complex according to claims. 2, 3, in which, based on the root-mean-square amplitudes, a map of the root-mean-square amplitudes is constructed and the thickness of the weathering crust of the pre-Jurassic complex is determined. 11. The method for determining the thickness of the weathering crust of the pre-Jurassic complex according to claims 2, 3, in which, when determining the composition of the Paleozoic bedrock at the deposit site, the deposit is divided into areas of no more than 30 km ² . 12. Method for determining the thickness of the weathering crust of the pre-Jurassic complex according to claims. 2, 3, in which the composition of the Paleozoic bedrock is determined as a result of the analysis of core material, interpretation of logging curves (GIS) and integration of these data in the field. 13. Method for determining the thickness of the weathering crust of the pre-Jurassic complex according to claims. 2, 3, in which the composition of the Paleozoic bedrock is determined as a result of gravitational, magnetic and electromagnetic measurements of the deposit. 14. A method for developing the weathering crust of the pre-Jurassic complex, in which: - based on well data, the elastic and density properties of the weathering crust of the pre-Jurassic complex and the roof of Paleozoic rocks are determined; - determine the convergence of the properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks; - in the absence of convergence of elastic and/or density properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks, based on seismic data, the presence of coal-bearing strata at the roof of the pre-Jurassic complex is determined; - in the presence of coal-bearing strata at the roof of the pre-Jurassic complex and when separating the phase of the weathering crust of the pre-Jurassic complex, the thickness of the weathering crust of the pre-Jurassic complex is determined on seismic data by subtracting the seismic reflecting boundary of the roof of the weathering crust from the seismic reflecting boundary of the base of the weathering crust; - constructing a well along the thickness of the weathering crust of the pre-Jurassic complex. 15. A method for developing the weathering crust of the pre-Jurassic complex, in which: - based on well data, the elastic and density properties of the weathering crust of the pre-Jurassic complex and the roof of Paleozoic rocks are determined; - determine the convergence of the properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks; - in the absence of convergence of elastic and/or density properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks, based on seismic data, the presence of coal-bearing strata at the roof of the pre-Jurassic complex is determined; - in the absence of coal-bearing strata at the top of the pre-Jurassic complex, with the same composition of the Paleozoic bedrock at the deposit site and in the absence of separation of the phase of the weathering crust of the pre-Jurassic complex, the thickness of the weathering crust of the pre-Jurassic complex is additionally determined using seismic data using root-mean-square amplitudes; - constructing a well along the thickness of the weathering crust of the pre-Jurassic complex. 16. A method for developing the weathering crust of the pre-Jurassic complex, in which: - based on well data, the elastic and density properties of the weathering crust of the pre-Jurassic complex and the roof of Paleozoic rocks are determined; - determine the convergence of the properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks; - in the absence of convergence of elastic and/or density properties of the weathering crust of the pre-Jurassic complex and the roof of the Paleozoic rocks, based on seismic data, the presence of coal-bearing strata at the roof of the pre-Jurassic complex is determined; - in the presence of coal-bearing strata at the roof of the pre-Jurassic complex and when separating the phase of the weathering crust of the pre-Jurassic complex, the thickness of the weathering crust of the pre-Jurassic complex is determined on seismic data by subtracting the seismic reflecting boundary of the roof of the weathering crust from the seismic reflecting boundary of the base of the weathering crust, and also in the absence of coal-bearing strata at the roof of the pre-Jurassic complex, with the same composition of the bedrock Paleozoic rock at the deposit site and in the absence of separation of the phase of the weathering crust of the pre-Jurassic complex, the thickness of the weathering crust of the pre-Jurassic complex is additionally determined on seismic data using root-mean-square amplitudes; - constructing a well along the thickness of the weathering crust of the pre-Jurassic complex. 17. A system for determining the thickness of the weathering crust of the pre-Jurassic complex, including at least one processor, RAM and machine-readable instructions for executing a method for determining the thickness of the weathering crust of the pre-Jurassic complex according to any one of claims. 1, 4-9. 18. A system for determining the thickness of the weathering crust of the pre-Jurassic complex, including at least one processor, RAM and machine-readable instructions for executing a method for determining the thickness of the weathering crust of the pre-Jurassic complex according to any one of claims. 2, 4-13. 19. A system for determining the thickness of the weathering crust of the pre-Jurassic complex, including at least one processor, RAM and machine-readable instructions for executing a method for determining the thickness of the weathering crust of the pre-Jurassic complex according to any one of claims. 3-13. 20. A machine-readable medium for determining the thickness of the weathering crust of the pre-Jurassic complex, containing machine instructions for determining the thickness of the weathering crust of the pre-Jurassic complex according to any one of claims. 1, 4-9. 21. A machine-readable medium for determining the thickness of the weathering crust of the pre-Jurassic complex, containing machine instructions for a method for determining the thickness of the weathering crust of the pre-Jurassic complex according to any one of claims. 2, 4-13. 22. A machine-readable medium for determining the thickness of the weathering crust of the pre-Jurassic complex, containing machine instructions for determining the thickness of the weathering crust of the pre-Jurassic complex according to any one of claims. 3-13.