UA80043C2 - Method for predicting hydrocarbon deposits - Google Patents

Abstract

The proposed method for predicting hydrocarbon deposits implies the analysis of changes of the mineral properties of rocks caused by external seismic effects. The method consists in processing the data on the controlled seismic profiles within the area of the three-dimensional seismic survey that are arranged at different angles to the planes of tectonic dislocations, determining the indicators that characterize the fissility of the rocks, simulating the seismic vibrations that correspond to the seismic profiles, correcting the parameters of the seismic survey by the results of the simulation, determining the nonuniformity of the bins, and determining the outlines and thickness of the deposits by comparing the data obtained at the seismic survey with the data obtained at the simulation. The proposed method is distinctive by its enhanced accuracy in predicting hydrocarbon deposits at areas with complex tectonic structure.

Description

Description of the invention

The proposed method refers to the geological field, in particular, geophysical methods of searching for minerals, and can be used to predict oil and gas deposits in traps of arbitrary type and solve other geological, geophysical and geoecological problems.

There is a well-known technique (1) that uses a complex of physical parameters, including anomalous absorption of elastic waves and characteristics of geophysical, geochemical and biophysical fields in order to increase the reliability of the prediction of hydrocarbon deposits. The method is based on a close relationship between the stress state of the massif of 70 rocks, physico-chemical and thermodynamic processes; the connection is manifested by the formation within anticlinal and synclinal structures and in the marginal part of the deposits of zones of increased and decreased mechanical stresses, which alternate with each other. Zones of abnormally low stresses correspond to areas of loosened rocks with increased fissures and porosity, favorable for the accumulation of oil, condensate, and gas. In plan, they correspond to concentric bands of isometric or irregular shape. The complex forecast is reduced to 72 applications of anomalies of physical parameters based on the data of two or three, less often four methods, one of which is seismic exploration.

However, this method has a general character due to the uncertainty of the criteria for a sufficient number of integrated methods and the lack of specificity of the requirements for the intensity, spectrum, power and other characteristics of the signals of each method in particular.

There is also a well-known method of forecasting oil and gas deposits (2), which includes seismic profiling by the common depth point method and gas surveying, in which the plan position and contours of zones characterized by the speed of longitudinal waves up to 50Ω/s and a depth of 100-400m from the surface of the earth are determined with the help of seismic profiling, after which a fragmentary gas survey for hydrocarbons is carried out within the contoured zone and in case of their presence /"detection/" a conclusion is made about the presence of oil or gas deposits. Ge)

The advantage of the method is the use of seismic data for the purpose of identifying the approximate location of low-velocity objects, which may also contain areas of gas-saturated rocks. The second advantage is the joint use of seismic surveying, the data of which indicate the location of the structure in the plan, and geochemical signs (|З), which are associated with accumulations of hydrocarbons or their migration paths and can confirm the oil and gas potential of the trap. "Her

The disadvantages of the method include the limited depth of forecasting and insufficient reliability of the connection of the detected complex anomalies with the deposit itself. It is known that in the zone of low velocities, which is usually associated with loose deposits of the Quaternary age, in the upper horizons of the original massif, water-saturated lenses of sandstones, peat, lignites, exits of groundwater from reservoirs, etc. can be distinguished by low velocities. "objects are not connected with deposits at depth. If near-surface formations are enriched with organic matter, which is oxidized, then biochemical anomalies of gases, including hydrocarbons, will create the illusion of the presence of hydrocarbon deposits. Fine diagnostics for screening false geochemical anomalies from those associated with with deposits, the method is not provided, although it exists and is given, for example, in work |41.

Geobotanical |5| are also known and biochemical (There are methods of searching for oil and gas deposits. The first of them Z 70 involves the selection of tree leaves in a special way, sealing them in containers filled with distilled and degassed water, degassing the mixture at a temperature of 18-202C and determining the content in the obtained gas phase " from individual hydrocarbons Based on the known effect of absorption of hydrocarbons by root systems from soil solutions, the anomalous content of hydrocarbon compounds is used to judge the oil and gas potential of a section.

The biochemical method involves taking samples of the dominant species of wood of at least three age categories, 75 determining the concentrations of vanadium and nickel in them, and assessing the oil and gas potential of the areas based on their increase according to the age categories. (ав) The positive aspect of the mentioned methods is the use of a specific composition of hydrocarbons that migrate from the actual deposits to the day surface. In addition, the advantage of the mentioned methods is obtaining integral information that is accumulated in a natural plant detector. This information, in contrast to gas surveys, is affected to a lesser extent by diurnal and other variations of the water and gas regime of soils. c However, the methods under consideration may not fix individual deposits, for example, dry methane gases and oils of a certain composition. This is due to the known selective sorption of paraffinic, naphthenic and aromatic hydrocarbons by plant organisms. In addition, some deposits will be missed when searching in conditions, for example, a powerful zone of infiltration of oxygenated waters, when the level of the ground cover and root system 59 can only be reached by individual products of the oxidation of the gas flow from the deposits. Another disadvantage is displacement

HF) halos of dispersion of hydrocarbons and products of their oxidation by groundwater and the impossibility of determining the probable depth of accumulation of hydrocarbons.

The closest in essence to the proposed one is the method of finding and contouring oil and gas deposits based on ZO-seismic exploration, which includes the excitation of seismic oscillations on profiles along the y axis with a step not less than 60 times the length of seismic waves in the medium, and the registration of signals on profiles along bands along the x-axis, processing of information with the preservation of valid amplitudes, editing of seismic records on non-longitudinal profiles, construction of sections and maps of relative attributes and subsequent forecasting of oil and gas deposits based on the analysis of the reflection of the epigenesis of the deposits of the productive section in the seismic attributes of the wave field according to their relative values |7 ) The method is based on changes in the seismic attributes of productive horizons and host rocks associated with epigenetic processes occurring in sediments around hydrocarbon deposits, as a result of changes in the geochemical potential of the environment in connection with the migration of hydrocarbons from the deposit, filtration through water-oil and gas-water contacts ( VNK and GVK), along cracks and microcracks and diffusion to the side and up along the section with accompanying secondary mineralization at a considerable distance from the deposit. The relative amplitude of horizons on seismic images is most sensitive to the specified changes in the structure of the geological environment.

The prototype provides point grouping of seismic receivers during signal registration, construction of graphs of the dependence of the most informative attributes of reflected waves on distance along the time axis within the normal field, editing of seismic records on non-longitudinal profiles of ZO-surveying in the process of data processing, and construction of /o detailed sections and maps of relative attributes in within productive deposits, which is the basis for a more reasonable prediction of the presence of deposits, the type of fluid in them and the definition of oil and gas bearing contours.

Along with obvious advantages, it also has significant disadvantages. The main ones are: - limited (relative to the depth of the research) observation apertures are used, which makes it impossible to use subcritical reflected and exchange waves to establish the /5 direction of propagation and parameters of rock massif fracture; - the impact of tectonic disturbances and fragmentation zones on the redistribution of hydrocarbon migration flows, the intensity of epigenesis and, accordingly, the contrast of their manifestation in seismic attributes, is not taken into account; - the deviation of the observation scheme from the design parameters and the unevenness of bins during ZO-surveying are not taken into account, which distorts the dynamic characteristics of seismic waves and causes the appearance of false anomalies on the sections of relative attributes, which can be identified with probable hydrocarbon deposits; - lack of integration with methods that are cheap to use and widely tested in different regions (remote and terrestrial spectrophotometry, near-surface geochemical research), which reduces the effectiveness of forecasting.

The basis of the proposed invention is the task of increasing the effectiveness of forecasting of hydrocarbon deposits due to more complete use of the seismic wave field, taking into account the influence of tectonic disturbances and crushing zones, as well as the peculiarities of the method and technology of conducting seismic (8) observations on the dynamic characteristics of waves and complexing with " "light" methods, in particular, remote and terrestrial spectrophotometry and near-surface geochemical research.

The task is solved by the fact that in the method of forecasting hydrocarbon deposits, which includes the use of ZO-seismic reconnaissance, information processing with preservation of valid amplitudes, construction of graphs of the dependence of the most informative attributes of reflected waves on the distance along the time axis within the normal - field, editing of seismic records on non-longitudinal profiles of ZO-surveying, construction of detailed sections and maps of relative attributes within productive deposits, subsequent forecasting and contouring of oil and gas deposits based on the analysis of the reflection of epigenesis of deposits of productive section in seismic attributes of

According to the invention, according to the WAVE field according to their relative values, due to the most promising anomalies of the so "deposit" (ATP) type, special control profiles are set, oriented at different angles in relation to the main disturbances, the profiles are worked out with an observation aperture, which provides for the registration of both pre-critical and and postcritical reflected longitudinal and exchange waves, based on the results of processing these data, the parameters of anisotropy and the directions of fracture zones of disturbances in the deposit-bearing geological environment are preliminarily estimated, the obtained data are used for multi-azimuth full-wave inc modeling, the results of the latter are used for editing seismic records on control profiles

And the data of ZO-surveying, in the future they carry out re-processing of the edited seismic records and form и? fields of seismic attributes, the latter are corrected for the deviation of the actual observation scheme from the design parameters and the established unevenness of the bins according to the modeling data, the values of the relative seismic attributes are specified based on the edited and corrected fields, a detailed volume model of the halos is built

Go! intrusion of hydrocarbons, reconcile it with the data of ground and remote spectrophotometric and near-surface geochemical surveys, after which the contours of the ATP in the section and plan are specified, and according to the coincidence of the characteristic anomalies with the places of exit of the vectors of traces of hydrocarbon flows and displacement planes on the day surface on the results of the integration of seismic exploration and the above "light" methods are more effective in predicting the presence of hydrocarbon deposits compared to the prototype. Compared with the prototype, the method has the following distinguishing features: 4) 1. Intra-method increase in the reliability of ATP selection by: - development of special control profiles oriented at different angles in relation to the anomaly of the "deposit" type with an observation aperture that provides for the registration of both pre-critical and and postcritical reflected longitudinal and exchange waves, which allows obtaining more reliable information about the location and structure of tectonic disturbances and epigenetically changed zones of the productive geological section on seismic

F) images, including in the upper part of the section; ka - editing of seismic records on control profiles and ZO-survey materials contributes to the reduction of disturbances caused by the influence of tectonic disturbances, including non-amplitude ones; 60 - correction of the seismic attribute fields for deviation of the observation scheme from the design parameters and the established unevenness of the bins according to the modeling data allows during the subsequent processing of the ZO-survey data to filter out anomalies associated with technological violations and imperfections in the field work methodology; - the use of remote and geochemical criteria of different genesis and depth and the study of the nature of the connection with the source of the anomaly increases the probability of identifying anomalies associated with the deposit and diagnosing false and indirect accumulations of chemical elements and compounds;

2. Inter-method integration based on: - the involvement of remote and terrestrial spectrophotometry and near-surface geochemical studies makes it possible to more reliably establish the contours of the ATP in section and area and to differentiate it into components, namely, the source of hydrocarbons, zones of epigenetic changes (channels and barriers migrations), as well as isolate heterogeneities not directly related to deposits. - construction of a volumetric model of ATP, which allows for purposeful statistical accumulation of useful signals of various methods and exclusion of interference signals, and to increase the reliability of the assessment of oil and gas potential prospects based on the identified ATP. 70 All the listed features are new compared to the prototype and their application allows solving the task.

The essence of the method is explained by the figure, where Fig. 1 shows the scheme of conducting special control seismic studies.

For explanation, the following symbols are used: reflection coefficients of longitudinal waves 1 for a homogeneous layer; 7/5 Coefficients of reflection of longitudinal waves when the profile is located along 2 and across the C cracking; reflection coefficient of exchange waves is 4 for a homogeneous layer; reflection coefficients of exchange waves 5, 6 when the profile is located along and across the cracking, respectively; day surface 7; geological environment 8; seismic boundaries 9; tectonic disturbances 10; excitation picket 11 oscillations; seismic receivers 12; incident 13 wave rays; rays of the ascending 14th wave; critical angle and 15; ZO 16 shooting range; profiles of 17 2o seismic images; the position of the tectonic disturbance in the plan along the basic reflective horizon 18a and the exit of the shifter plane under the Quaternary deposits 186; control profiles across rock disturbance 19; control profile at an angle of 45 to a violation of 20; control profile along rock disturbance 21.

Figure 1a, built on the basis of modeling, shows that depending on the direction of propagation of the cracking zones (faults) and the azimuth of the profile, the ratio of the intensity of the reflected longitudinal waves 1, 2, 3 and exchange 4, 5, 6 waves in the closed region is significantly different.

Thanks to this, it becomes possible to more reliably establish i) tectonic disturbances and determine their physical properties on seismic images.

Figure 1b6 shows a diagram of observations on the profile, where it can be seen that pickets receiving 12 oscillations are located both in the subcritical region and in the critical parts of the wave field in relation to the deepest reflecting horizon.

To determine the overall aperture for the reception of vibrations, the critical angle 15 of the incidence of seismic waves on the above-mentioned boundary 9 is preliminarily determined. The registration of the seismic rays 14 of the ascending waves corresponding to the critical angle 15 is performed at a distance from the excitation picket 11 of the vibrations according to the formula: "c)

Khkr-2nidi (1) so where H is the depth of the deepest horizon, and is the critical angle.

However, such an aperture will not be sufficient for reliable determination of the position and physical properties of violations. Therefore, the oscillation registration base is increased by replacing the angle i in formula (1) with the value (ini/2). "

The latter follows from the simulation results. In this case, the maximum distance of seismographs from З7З s 70 source of oscillations is: ; with" Htakh-2Nid(no/2) (2)

To reduce the overall aperture of observations, the research is carried out with an offset determined by the formula: (ee) o Khtip-2NIU(I2) (3) (ав) This is sufficient for tracing waves in the area where the wave reflection coefficients on profiles with different orientation azimuths are 50 quite close.

Figure 1c shows the layout of control profiles within the ZO-surveying polygon. As can be seen from this figure, the majority of control profiles are placed across the faults, 2-3 profiles across the faults and at least one profile at an angle of 459 to the direction of propagation of the main fault. In the case of their more complex configuration in plan and unequal traceability in depth (depths of attenuation of fault amplitudes), the number of control profiles is increased, but the principle of the location of the profiles remains the same, i.e., the main part of the control profiles is projected across the violations being investigated.

The main task in the process of data processing is the selection of tectonic disturbances on the images, i.e.) determination of the directions and parameters of rock fissure zones and their relationship with productive horizons (deposits). The latter determines the possible type of trap and the corresponding ATP anomaly, the preservation of hydrocarbon deposits. At the same stage, the impact of disturbances on the structure of the primary seismic records and the integrated picture on the ZO-survey images is evaluated. Full-wave modeling is an essential element of wave field analysis and determination of rock fracture parameters. One of its implementations can be the well-known "Tezzega!" package. The ultimate goal of the conducted analysis is to identify individual parts of seismic images with the influence of tectonic disturbances and exclude them from the attribute analysis aimed at establishing 65 traces of effusion-diffusion flow in the form of epigenetically altered rocks, or editing the primary records of control profiles and ZO-survey materials in accordance with the change reflection coefficient depending on the profile azimuth. At this stage, modeling plays a crucial role.

To increase the forecasting efficiency, the seismic attribute fields are corrected for the deviation of the observation scheme from the design parameters, as well as the unevenness of the bins established by the simulation results. Such a correction is especially necessary when the corresponding corrections exceed the background level of the attributes.

Attribute analysis of the seismic wave field, despite its known effectiveness, is insufficient for predicting hydrocarbon deposits. The detected anomalies may be related not only to epigenetic changes of rocks under the influence of hydrocarbon flows or "degassing pipes" above oil and gas deposits, but also to other 7/0 inhomogeneities. Therefore, in the process of forecasting hydrocarbon deposits, there is a need to involve relatively cheap, but effective methods. Such methods include remote and ground photometry, which is based on the analysis of the optical characteristics of vegetation based on the materials of aerial photography and ground research. Morphological changes in vegetation in the area of hydrocarbon deposits lead to changes in their optical characteristics (reflection and fluorescence spectra, scattering indicators, etc.), which is reflected on the corresponding parameter maps in the form of anomalies in certain parts of the electromagnetic radiation spectrum.

For the same purpose, direct geochemical methods based on the study of free and sorbed hydrocarbons and non-hydrocarbon gases in the near-surface part of the section are involved.

The final stage of forecasting is the determination of the depth and location of the productive part of the 2o section and the type of hydrocarbon fluid in the field of relative amplitudes based on the study of the thicknesses of the recovery zone (in the presence of "bright spots" on the images). Above oil deposits, the thickness of the renewable zone is about 200-300 m, above gas deposits - 500-600 m and more. For the same purposes, the ZAV-analysis (dependence of the amplitude on the distance) is involved.

The method is implemented as follows. high school

In the area where the 2.5 or З3О survey was performed, tectonic disturbances are identified that control probable hydrocarbon deposits, or, on the contrary, lead to their disintegration. Disturbances are approximated by piecewise linear i) segments. Orthogonal to them, control profiles with a length that is at least 2 times greater than the depth of research on each side of the breach are set. The number of such profiles is determined by the number of breaks on the approximation line. Depending on the length of the straight lines within the fault and the behavior of the seismic attributes, the number of profiles can be either reduced or increased. In addition to the main ones, control profiles are set along the violations (2-3 profiles) and at an angle of 452 to the violations, the number of the latter does not exceed the number of the main control profiles. at

Full-wave azimuthal modeling is carried out with the parameters of the anisotropy of the environment ( there are 5), which are as close as possible to the conditions of conducting research. At the same time, a priori data obtained during the drilling of wells directly on the research area and on adjacent areas, data of geophysical studies from wells and results of seismic exploration for previous years are used.

According to the simulation results (for longitudinal and exchange waves), the dependences of A пп(Х) and Аре(Х) are determined for the cases of a homogeneous layer and placement of profiles across and along anisotropic sections. They also calculate the derivative dependencies Arr vpod/Arr odnore Arr vpop/Arr odnor Ar vpod/Are odnore Ar vpop/Lre odnor. A seismic section is constructed within the most submerged part of the sediments under investigation and seismic - c rays corresponding to the critical angle are modeled, then the most optimal scheme of observations with c is determined taking into account formulas (2 and C). "» The main control profiles are worked out, their initial processing is carried out, and then the placement of the remaining control profiles is edited.

After working out the profiles, a detailed attribute analysis is carried out for each of them, the data are compared with the (ee) simulation results, and the anisotropic properties of the environment within the tectonic disturbances and the most likely directions of cracking are determined. In addition, they study the influence of fracturing on the values of seismic attributes on the ZO-survey materials and edit the source seismic records according to control profiles and data av | Z0 shooting.

Editing is carried out by introducing corrective corrections in the intervals of the seismic records corresponding to the fractured intervals according to the expression "

AND

AKA - kine; -Ав) щ 25 here do and Ав are wave amplitudes, respectively, for a homogeneous stratum and for a fractured stratum according to modeling data at an azimuth that coincides with a specific control profile of the ZO-surveying system; име) K is a coefficient that binds model and actually observed data and can be calculated based on the ratio of wave amplitudes in the subcritical part of the wave field. 60

K-Aspos/Amod. (5)

Correction factors for the working pattern and unevenness of the bins, determined on the basis of simulation, are also entered into the attribute fields before determining the relative values. 65 Seismic boundaries (known to be tied) are applied to the corrected fields, along which, within narrow time windows (0.020-0.040s), the behavior of one or another attribute is studied using a special technology that ensures the construction of sections and maps of relative seismic parameters. This procedure significantly reduces the impact of various types of obstacles related to the methodology and technology of work and surface conditions.

Probable hydrocarbon deposits and their surrounding altered zones are identified and outlined on the maps of relative attributes, and the details of their structure are clarified by cross-sections. This stage ends with the formation of a three-dimensional model of the oil and gas reservoir, which may also include complicating elements, namely, tectonic disturbances and zones of plicative and dilatational fracturing, zones of catogenetic transformations, lithological-stratigraphic screens and areas of increased permeability in the layers of rocks covering the deposit. Depending on the type of fluid, the scale of oil and gas capacity, tectonic disturbances, the age of deposits and other reasons, the configuration and 7/0 Intensity of the manifestation of deposits and their borders will differ (I8). For example, oil deposits will correspond to a relatively small (200-300 m) reducing zone ("bright" spots) on sections of relative amplitudes, which passes from above into an oxidizing zone ("dull" spots). Above the gas deposits, the height (thickness) of the recovery zone is much greater and can reach 700-800 m. To determine the type of fluid is also involved

ZAV analysis.

The contours of the deposit in the plan are determined by sections of sharp gradient changes in seismic attributes (in particular, the field of relative amplitudes).

An example of the implementation of the method.

To fully implement the method, it is necessary to carry out special studies with the design and production of the entire complex of works.

In part, the proposed complex can be considered tested on Kadnytsia Square (north side

DDZ), where in different periods 20-seismic research, remote (multi-zone space photography) and ground photometry were carried out, and a little later - geochemical research in the near-surface zone (depth 1m and 3m) for the content of free and sorbed hydrocarbons, as well as ground measurements of concentration and streams of hydrocarbon gases, mercury, helium, etc. in soils and soil-forming rocks. high school

The research was carried out in connection with the recommendation to drill 4 dependent wells within the tectonic block, which was identified on the basis of 20O-seismic research by the East Ukrainian Geophysical (8) exploration expedition of the Ukrgeofizika DGP.

Modern seismic surveys of ZO were not carried out, therefore, only materials were processed according to the available profiles. A total of 14 profiles are involved. On each of the profiles, sections of relative amplitudes and s s of Anomaly maps (of the deposit type) were constructed for the main seismic horizons of the Bashkir (Mb), Serpukhov (Uv?), "Viseyian (Uvo.d) carbon layers and the weathering crust of the basement.

The Institute of Geological Sciences of the National Academy of Sciences of Ukraine constructed maps of optical anomalies of varying degrees of intensity based on the materials of multi-zonal space photography and ground-based spectrophotometry. Av

Geochemical studies carried out by the Ukrainian State Geological Survey Institute and

Together with the Institute of Geology and Geochemistry of Combustible Minerals of the National Academy of Sciences, we completed the construction of maps of the content of free and sorbed hydrocarbons at a depth of 3 m and 1 m, as well as maps of the content of gases in the soil and gas flows from the subsurface to the atmosphere.

Figure 2 (on 2 sheets) shows fragments of some of the obtained maps in the area of well 1, which was the first to be drilled within the Kadnitsky block even before the completion of complex studies. The following designations are adopted on the map fragments: - 70 Fig. 2a - 1 - isogypses of the reflective horizon of the MV" (C1m2), 2 - discontinuous disturbances, C - discordant discharges; c predicted deposits: 4 - oil, 5 - condensate, 6 - gas; z» Fig. 2b - 1 - contours of optical anomalies; 2 - promising areas according to remote (space) survey data for staging detailed works;

Fig. 2c - the content of free hydrocarbons at the depth of Zm: 1 - less than the conditional background (0.0005 volume percent), 2 49. 0.0005-0.0106.95, C - anomalies greater than 0.0106.95; the content of free hydrocarbons at their depth: 4 - less than the conventional background (0.0005 volume percent), 5 - 0.0005-0.106.95, 6 - anomalies greater than 0.0106.905; (ав) Fig. 2d - the content of sorbed hydrocarbons at the depth of Zm: 1 - less than the conditional background (0.005 cm/kg of rock), 2 - about 0.005-0.01 cm Z/kg, Z - anomalies greater than 0.01 cm Z/kg; the content of sorbed hydrocarbons at their depth: 4 - less than 5r of the Conditional background (0.005cm/kg of rock), 5 - 0.005-0.1cmZ/kg, 6 - anomalies greater than 0.1cmZ/kg. o The map of selected anomalies of the deposit type according to seismic research data on the Upper Visean horizon 4) (Fig. 2a), which largely characterizes the productivity of the weathering crust of the foundation, indicates that well 1 is located outside the anomaly of the deposit type (ATP). According to the data of the GDS, the section of the weathering crust was characterized as oil and gas saturated, but no hydrocarbons were obtained during the well test of industrial inflows.

Figure 26 shows the results of remote and ground photometric studies on the same area. (F) A minor optical anomaly, consisting of three areas, was identified northwest of the well. ka It can be concluded that the well is not in optimal conditions.

The results of near-surface geochemical studies on the content of free and sorbed hydrocarbons (Fig. 2vg) also do not give grounds to talk about the optimality of well placement. In particular, on the map of the content of free hydrocarbons there is no anomaly in the area of the well, but on the map of the content of sorbed hydrocarbons at their depth, a slightly increased content is observed (0.005-0.1 cm Z/kg), at the same depth, the content of hydrocarbons is below the background.

The increased content of hydrocarbons at both depths is noted in the north and northwest (in the area of the completed drilling site). 65 The obtained data on the complexation of methods indicate the suboptimal construction of the Moe1 well. According to the given materials, it would be more reasonable to drill a well 1.0-1.2 km to the northwest. In general, the area where the Kadnytska-1 well is located is not the most promising in this area.

The next step is the comparison and comparative analysis of the seismic three-dimensional model of the deposit and associated zones of secondary rock changes under the influence of hydrocarbons with planar information of "light methods - spectrophotometry and geochemical studies. At the same time, the mapped parameters of ground surveys are compared with the configuration of the deposit and adjacent to it fracture zones, "degassing pillars" and "intrusion haloes" of hydrocarbons and other migration channels. Next, the projections of the exit of hydrocarbon migration traces to the bottom surface are determined by the vectors of the migration channels, the corresponding optical and geochemical anomalies are identified with the corresponding elements of the models of the oil and gas-bearing part of the geological environment, and the anomalies are screened out other 7/0 origin, for example, landscape and man-made.

Fig. 3-5 shows the comparison schemes of the deep geophysical model of the anomaly of the "deposit" type (dark color) (a), the corresponding temporal seismic image (b) and fragments of maps (c) and graphs (d) of the distribution in the soil at a depth of 0, 7m of gaseous mercury Na (Fig. 3), CH methane (Fig. 4) and the coefficient of fat content of hydrocarbon gases sorbed by flowmeter tubes (Fig. 5). The latter is equal to the ratio of the content of heavy /5 hydrocarbon gases U; Explosives (from ethane) to the methane content in this gas mixture. This indicator most reliably reflects the oil and gas capacity of deep horizons, since heavy hydrocarbons in the upper part of the section, including soils are not formed.

The comparison is given for the submeridional seismic profile 16, which is located in the western part of the site and captures the marginal part of the anomalous geochemical field (see Fig. 2).

Fig. 3 shows that the southern tectonic boundary of the Kadnytsk fold with the Kuzmychiv structure is manifested by mercury anomalies extending to the Mob0 seismic picket. The zone of secondary rock changes under the influence of the hydrocarbon flow is reflected by a low-contrast gradual increase in the concentration of gaseous mercury in the soil, which corresponds to modern models of mercury anomalies over the deposits (9).

Fig. 4 shows that the methane flow registers part of the zone of tectonic disturbance (with displacement) and is characterized by anomalies of weak contrast - places of catagenetic transformations close to the day surface. That is, the methane flow vector is shifted according to the configuration of the "halo invasion" of hydrocarbons into the containing medium.

Fig. 5 confirms that a certain part of heavy hydrocarbons also migrates along the plane of the displacer of the disturbance, however, the main flow associated with the probable deposit is concentrated between pickets 72-135 of profile 16. со

Thus, the analysis of the negative results of the drilling of the Kadnytska well based on the integration of seismic exploration, ground and remote spectrophotometry and near-surface Z geochemical surveying, as well as the determination of a promising oil and gas-bearing interval along the profile at 162524 40 90 (SUGRE) indicate the feasibility of using of the proposed complex for forecasting oil and gas fields. at

Implementation of the method in its entirety, from the design and staging of field work to data processing and complex interpretation, will increase the efficiency of oil and gas exploration in areas characterized by a complex tectonic structure.

Sources of information 1. Karus V.E., Kuznetsov O.L., Kyrychek M.A. The problem of direct oil and gas field searches by geophysical and geochemical methods: achievements and prospects / Sov. Geology, 1981, Mo3. - P. 3-6/. шщ с 2. The method of forecasting oil and gas reserves / E.E. Zemtsov, Y.P. Malovytskyi, N.P. Shkirman, A.N. and Korobeynyk. AS USSR, Mo972452. OIM11/00. Publ. 07.11.82/. "" Z. The method of complex forecasting of oil and gas-bearing local structures / V.A. Averyev, R.I.

Andreeva, E.K. Balytskaya et al. - Kyiv: Nauk, dumka, 1982. - 196 p./. 4. Starobinets I.S. Formation of anomalous geochemical fields on unproductive areas and criteria for their search evaluation / Geologiya neft i gaz, 1992, Mo3. - P.40-43/, 5. Geobotanical way of searching for oil / G.Yu. Valukonis, V.G. Lizard AS USSR, Mo1402996. (з0О1ИМ9/00. о Publ. 15.06.88G./. о 6. Biogeochemical method of searching for oil and gas prospects / G.Yu. Valukonis. A.S. USSR,

Mo1755233. SOIM9/00. Publ. 15.08.92/. 7. The method of finding and contouring hydrocarbon deposits / N.Ya. Marmalevskyi, G.V. Meged, S.G. Semenova, se» O.I. Semenets, D.M. Kovalev. Declaration patent of Ukraine Mob7031A. SOIIIM1/00, O1M1/28. Publ. 15.06.2004 /prototype/. 8. Sahibchareev R.S. Secondary changes of collectors in the process of formation and destruction of oil wells

Depends. - L.: Nedra, 1989. - 260p. 9. Fursov V.3. Detection and evaluation of superimposed geochemical anomalies of mercury in closed territories (F, at MGHC-200 / Methodical recommendations, M., 2001, - 153 p./name)

Claims (1)

The formula of the invention The method of forecasting hydrocarbon deposits, which includes conducting ZO-seismic reconnaissance, processing information with the preservation of valid amplitudes, constructing graphs of the dependence of the most informative attributes of reflected waves on the distance along the time axis within the normal field, editing seismic records on non-longitudinal 65 ZO survey profiles, construction of detailed sections and maps of relative attributes within productive deposits and subsequent forecasting and contouring of oil and gas deposits based on the analysis of the reflection of the epigenesis of deposits of the productive section in the seismic attributes of the wave field according to their relative values, which differs in that due to the most promising anomalies of the deposit type (ATP) set special control profiles oriented at different angles in relation to the main disturbances, the profiles are worked out with an increased observation aperture, based on the results of processing these data, the parameters of anisotropy and the directions of the fracture zones of the disturbances in the geological environment containing the deposit are preliminarily estimated, the obtained data are used for multi-azimuth full-wave modeling, the results of which are used to edit seismic records based on controlled profiles and ZO-survey data, in the future the edited seismic records are re-processed and form t fields of seismic attributes, which are adjusted according to 7/0 Deviation of the actual observation scheme from the design parameters and the established unevenness of bins according to modeling data, according to the edited and corrected fields, the values of relative seismic attributes are specified, a detailed three-dimensional model of hydrocarbon intrusion halos is built, and it is reconciled with data of ground and remote spectrophotometric and near-surface geochemical surveying, after which the contours of ATP are specified in section and plan, and according to the coincidence of characteristic anomalies with the places of exit vectors of traces of hydrocarbon flows 7/5 and planes of mixers on the day surface according to the results of comprehensively taken into account seismic data and spectrophotometric data and geochemical studies predict the presence of hydrocarbon deposits. c schi 6) (ze) « «c) «c) d) - and? (ee) («c) («c) sh» syu» ime) 60 b5