RU2097796C1 - Geochemical approach to hydrocarbon prospect - Google Patents

Abstract

FIELD: hydrocarbon deposit prospect. SUBSTANCE: invention aims at searching hydrocarbon deposits directly from surface without resort to mine opening and drilling boreholes. To this aim, a small group of mobile forms of elements indicative of hydrocarbon in question are extracted from soil, namely those elements bound with soil organics as well as elements in electromobile forms from humus level of soil A1 and elements bound with iron-manganese compounds from soil level C enriched with that kind of compounds. Areas are further selected combining lots with abnormally high concentrations of all selected element-indicators contained in all extracts and, from position of these areas, frontiers of oil and gas-bearing provinces, regions, and fields or individual deposits are established depending on testing scale. EFFECT: facilitated hydrocarbon prospect. 2 dwg

Description

 The invention relates to geochemical methods of searches and can be used to assess the oil and gas potential of the territories and searches for oil, gas, bitumen.

 A known method of searching for deposits of oil and gas (ed. St. N 1224764, class G 01 V 9/00, 1986), in which directly at the test point separate extraction is soluble in weak acid and water-soluble forms of metals from rocks. The location of oil and gas deposits is judged by the coincidence of anomalously increased values of the products of normalized concentrations of metals dissolved in weak acid and anomalously increased values of this parameter for water-soluble forms.

 The disadvantage of this method is that the chemical elements pass into the acid hood in various forms of finding, which significantly reduces the contrast of the anomalies and does not allow to unambiguously distinguish oil deposits, a useful signal from which is weak and difficult to stand out against a high, often dramatically changing background.

 There is also known the biogeochemical method of searching for oil and gas deposits (ed. St. N 894658, class G 01 V 9/00, 1981), in which at each sampling point they simultaneously take samples of the humus horizon of the soil and the dominant vegetation, determine the content in them metals, for example, iron, manganese, copper, cobalite, zinc, chromium, and in vegetation, in addition, also phosphorus and boron, and according to the ratios of the concentrations of metals in vegetation and in the soil and the increased values of boron and phosphorus contents in the vegetation localize the position of the hall and oil and gas.

 The disadvantage of this method is the low accuracy of the allocation of deposits due to changes in the nature of vegetation along the line of the observed profile.

A known method of lithogeochemical searches, including soil sampling, their abrasion and the subsequent determination of the gross contents of a large number of chemical elements by spectral analysis (Instructions for geochemical methods for searching ore deposits. M. Nedra, 1983, pp. 69 - 109)
The disadvantage of this method is the impossibility of isolating a useful signal from an oil deposit by gross concentrations of chemical elements in the soil, since this signal is associated with mobile forms of finding chemical elements, which make up a fraction of a percent of the gross content.

 Closest to the proposed is the geochemical method of searching for oil and gas deposits (ed. St. N 913313, class G 01 V 9/00, 1986), in which mobile forms of chemical elements are extracted from crushed rock samples, their content in the extractant is determined by anomalous the values distinguish oil and gas structures.

 The disadvantage of this method is the uncertainty of the range of analyzed forms of finding chemical elements, which often does not allow to identify an abnormal signal from an oil reservoir against a background of changing concentrations of mobile forms of finding chemical elements due to landscape factors. In addition, the additional operation of grinding the sample leads to an increase in the complexity of the work and distortion of the results by changing the equilibrium between the forms of location that originally existed in the sample.

 The objective of the invention is to create a technology for the search for hydrocarbons, which involves research directly from the surface without excavating mines or wells, does not require crushing of rock samples and at the same time allows you to reliably establish the boundaries of not only individual fields or deposits, but also oil and gas provinces and regions.

 The problem is solved due to the fact that in the method consisting in sampling and extraction of chemical elements from them in mobile forms of finding, followed by determination of their concentrations in the extract and allocation of zones with abnormally high concentrations of elements, soil samples are taken from the upper humus horizon A1 and horizon C enriched with iron-manganese compounds. At the same time, hydrocarbon indicator elements associated with organic compounds are extracted from horizon A1 sample. and soil from sample C layer extracted produce hydrocarbons indicator elements associated with iron-manganese compounds. In addition, at the same point in a natural occurrence or from a selected sample of one of these horizons under the influence of a constant electric current, the hydrocarbon indicator elements are extracted in electrically mobile forms. Then, in each of the extracts, the concentrations of indicator elements pre-determined for a given region are determined and according to the data obtained within the studied territory, areas of zones coincidence with anomalous concentrations of the most contrasting indicator elements for each extract are identified. Comparing the data obtained from the three extracts, the areas within which the coincidence sections of the anomalous zones identified by the various extracts are combined are distinguished. The location of such areas establishes the boundaries of oil and gas provinces, regions, fields or individual deposits depending on the scale of testing.

 The differences from the known methods are as follows.

 When searching for oil, it is supposed to extract only a narrow group of mobile forms of elements from the soil, while the previously used methods involved the extraction of a wide range of forms of chemical elements in the soil or the extraction of an indefinite range of mobile forms of elements from rocks samples.

This was made possible thanks to the studies of the authors, which made it possible to establish the phenomenon of jet subvertical migration of chemical elements from oil and gas deposits to the surface, which consists in the fact that
a deep geological object (deposit, hydrocarbon field) serves as a source of indicator chemical elements, usually in the form of charged ions (in electromobile forms of location);
indicator elements in electromobile forms of finding are capable of long-distance migration, including to the day surface; migration is carried out in the form of jets stretching from an object to the surface;
during a sharp change in physical and chemical conditions on the day surface, indicator elements coming from the depth partially interact with the constituent components of the soil, are fixed and accumulate in it; analysis of soil composition showed that the maximum accumulation of indicator elements migrating from depth occurs on organic soil compounds, in particular fulvates and humates, and on its iron-manganese formations;
on empty areas where deep geological objects of the type in question are absent, anomalous concentrations of indicator elements in moving forms are not much more noticeable. Their geochemical background is low and stable.

 A combined selective analysis of indicator chemical elements in electromobile forms of their presence, their compounds with the organic phases of the soil and its iron-manganese formations makes it possible to sharply increase the useful signal from oil and gas-bearing objects even against the background of a dramatically changing landscape. In some cases, for example, in desert regions with undeveloped soil cover, indicator elements in some of the indicated forms of location may be absent. Then the lack of information is compensated by the contribution from other forms of finding. At the same time, as a result of testing, “white spots” remain due to the lack of a representative horizon, and the reliability of the search increases.

 Another difference is the need for selective extraction of mobile forms of finding indicator elements from different depths of soil horizons, namely from those horizons where the concentration of these forms of finding is greatest. Thus, the extraction of compounds of indicator elements with organic phases is carried out from the upper soil horizon A1, the richest in humus, and their compounds with iron-manganese soil formations from horizon C, usually enriched with iron and manganese. The involvement of various soil horizons in the analysis in some cases makes it possible to exclude the possible effect of technogenic surface pollution.

 In addition, the authors' studies carried out by regional profiles showed that increased concentrations of indicator elements in the forms of finding involved in this method are observed not only over oil and gas deposits, but also within oil and gas provinces and regions. Therefore, the method allows you to select, depending on the scale of the survey, not only individual deposits, but also oil and gas provinces and regions.

 The proposed method can also be used to search for gas fields, bitumen deposits, since it is known that many of the chemical elements (nickel, vanadium, cobalt, etc.) are present in natural gas, bitumen and can be indicator elements in the search for deposits of these hydrocarbons.

 Figure 1 shows the results of observations of the proposed method when searching for oil in two areas of the Kaliningrad region: a observation of an oil deposit, b over a structure identified by seismic data, but without signs of oil according to drilling data; in FIG. 2 results of observations of the proposed method for geotraverse "Granite".

The method is as follows:
Depending on the tasks being solved, they are set by the shooting scale, the distance between the profiles and observation points is determined. So, for regional studies (contouring of oil and gas provinces, regions), the distance between observation points is from 500 m to 5-10 km. To search for deposits and individual deposits, the distance between observation points is 50 100 m with an expected length of deposits of up to 2 4 km (Kaliningrad region) and 100 250 m with an expected size of deposits of tens of kilometers (Western Siberia).

 On the study area, at each observation point, samples are taken from different soil horizons. Samples are taken in separate bags from the upper humus horizon A1 and a sample from the subsoil layer C. Samples are dried in air and transported to the extraction site. At the same observation point, extraction of electromotive forms of the presence of chemical elements in a natural occurrence using a constant electric current is possible. For this purpose, special devices for receiving elements (vessels filled with a solution of acid separated from the soil by a semipermeable membrane and connected to a source of constant electric current) are installed in the soil. A constant electric current is passed through the element receivers for a predetermined time, after which the acid solution is sent for chemical analysis.

 From a sample of the upper humus horizon A1, chemical elements associated with soil organic compounds are extracted. The extraction is carried out with selective solvents of organic compounds of the soil, for example, sodium pyrophosphate solution or alkali solutions (NaOH, KOH). From a sample of horizon C, chemical elements associated with iron-manganese compounds are extracted. Extraction can be carried out with various selective solvents, but it is most effective to conduct thermal firing of samples, in which magnetite is formed, followed by magnetic separation of the sample. The extraction of electromotive forms of finding can also be carried out in laboratory conditions from selected soil samples.

 Based on elemental analyzes of hydrocarbon feedstocks in the region of work, a circle of indicator elements is established and a determination is made in all prepared extracts of these elements. Indicator elements can also be determined on the basis of experimental and methodical work in the region on a site with a known deposit. Moreover, the analysis of extracts is carried out on an extremely wide range of elements, from which those that have abnormal concentrations are isolated. Studies have shown that both metals (nickel, cobalt, vanadium, zinc, etc.) and non-metals (bromine, chlorine, etc.) can act as indicators of oil.

 For each indicator element for each extract, zones with abnormal concentrations of this element are determined individually. Further, for each extract, the areas of coincidence of anomalous zones are determined by several of the most contrasting indicator elements. To do this, you can use a multiplicative or additive indicator in which for each observation point, respectively, the product or the sum of the concentrations of all indicator elements is used. The abnormal area is distinguished by the anomalous value of the multiplicative (additive) indicator. The final stage of processing the results is the selection of a promising area, within which there is a coincidence of the areas allocated according to the analysis of each of the extracts. For this purpose, for example, a complex indicator can be used, which is the product (sum) of multiplicative (additive) indicators for each of the extracts. It is also possible to isolate a promising area by simply superimposing the contours of anomalous areas, selected according to the analysis of each of the extracts.

 In FIG. 1 shows an example of the implementation of the method for oil searches at two sites in the Kaliningrad region. In the study of the chemical composition of the oils in this region, it was found that they contain elevated concentrations of such chemical elements as nickel, cobalt, zinc, manganese. These metals were taken as oil indicator elements for the region. In the first section (Fig. 1, a) of drilling with oil wells, the oil and gas deposit is at a depth of 2 km. When testing soil from the surface along the profile, it can be seen that the flank parts of the deposit are clearly marked by increased values of the complex indicator, which is the product of the concentrations of nickel, cobalt and zinc in electromotive forms of occurrence, in the compounds of these metals with organic complexes of soils and with iron-manganese compounds. In the second section, as a result of seismic work, an anticlinal structure was identified that was prospective for hydrocarbons, however, according to the results of drilling two wells, there were no signs of oil, and the structure was considered unpromising. As a result of work by the proposed method, abnormal concentrations of metals over this structure were not detected (Fig. 1, b).

 Figure 2 shows the results of observations of the proposed method for geotraverse in the European part of Russia. Anomalous concentrations of indicator elements are noted in the Volga-Ural and Dnieper-Pripyat oil and gas provinces. The observation results of the proposed method indicate that the area west of the known contour of the Volga-Ural oil province is also promising for the discovery of hydrocarbons. Currently, intensive search work is underway in this territory.

Claims (1)

 The geochemical method of searching for hydrocarbons, which consists in sampling and extracting chemical elements from them in mobile forms of finding, followed by determining their concentrations in the extract and identifying zones with abnormally high concentrations, characterized in that at each observation point soil samples are taken from the upper humus horizon A1 and horizon C enriched with ferromanganese compounds, and extraction of hydrocarbon indicator elements associated with organic by soil compounds, from a sample of layer C, hydrocarbon indicator elements are extracted that are associated with ferromanganese compounds, in addition, at the same point in a natural occurrence or from a selected sample of one of these horizons, the hydrocarbon indicator elements are extracted into electrically movable under the action of direct electric current forms, determine the concentration of pre-installed indicator elements in each of the extracts, identify areas of coincidence of zones with abnormal concentrations on For more contrasting indicator elements for each extract, areas are identified within which coincidence areas identified by different extracts are combined, and the boundaries of the oil and gas provinces, regions, fields, or individual deposits are established by the location of these areas, depending on the scale of testing.

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