RU2359290C1 - Forecast method of hydrocarbon accumulation - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention relates to gas-geochemical searches of oil and gas deposits and can be used at prospecting works for oil and gas. Essence: successively there are selected samples of subsoil gas from boreholes on two horizons: top (0.3-0.4 m) and bottom (0.8-1.0 m), preliminarily encapsulating each interval of the atmosphere. It is implemented gas-geochemical analysis of content of methane and heavy hydrocarbons. At increasing of gas concentration of its background values not less than two times and increasing of concentrations on bottom horizon relative to top not less than 1.5 times, it is concluded about affirmative forecast of hydrocarbon accumulation.

EFFECT: forecast effectiveness increase.

3 cl, 1 dwg

Description

The invention relates to the field of gas and geochemical searches for oil and gas fields and can be used in oil and gas exploration based on determining the amount of hydrocarbon gases from oil and gas fields in the subsoil layer of the region, where common geological and geophysical features positively characterize the possibility of detecting oil and gas deposits.

There is a known method of searching for oil and gas through seismic exploration, but it is expensive and time-consuming, since it requires the drilling of many wells and seismic studies. Often, geochemical or gas-geochemical research methods are used previously to assess oil and gas content.

Gas-geochemical methods for finding oil and gas deposits have been used since the 30s of the last century. They are based on the theory of fluid and gas migration from the bowels to the surface. If an oil and gas deposit is located in the bowels, then abnormal fields of hydrocarbon gases are formed on the surface of the earth. These gases are sampled and analyzed on gas chromatographs.

The main advantage of the gas-geochemical method is the speed and low cost of the experiment. The disadvantage is the difficulty of interpreting the results, since due to the mobility of the gases it is difficult to determine the location of their source. In addition, microbial gases are formed on the surface of the earth, which in composition can be similar to the gases of oil and gas fields, and even surpass them in quantity. This and other manifestations make it difficult to make a correct gas geochemical forecast.

There is a known geochemical method for searching for hydrocarbons, which consists in sampling at each observation point from the upper humus horizon (Al) and horizon (C) enriched with ferromanganese compounds, and hydrocarbon indicator elements associated with organic soil compounds are extracted from the horizon sample (Al), from a sample of the layer (C), hydrocarbon indicator elements associated with ferromanganese compounds are extracted. In addition, at the same point in a natural occurrence or from selected samples of one of these horizons under the influence of a constant electric current, hydrocarbon indicator elements are extracted in electrically mobile forms, the concentration of predefined indicator elements in each of the extracts is determined, areas of coincidence of zones with abnormal concentrations of the most contrasting indicator elements for each extract, allocate areas within which coincide areas identified of various extracts, and on the situation of these areas determine the limits of oil and gas provinces, regions, fields or individual deposits, depending on the scale of sampling (p. RF №2097796).

The disadvantages are the complexity, high material costs for the implementation of the method and the difficulty of interpreting the data.

A known method for determining the presence of zones or zones of a hydrocarbon anomaly by conducting a geochemical survey of the study area for traces of hydrocarbons in snow samples, used, as a rule, for marshy terrain. Two stages of geochemical survey of the investigated area are carried out. Both stages are carried out on snow cover. At the first stage, the presence of a zone or zones of hydrocarbon anomalies is determined. To do this, the study area is divided into a regular rectangular grid, samples are taken, and then their laboratory analysis is carried out to determine the hydrocarbon content, as a result of which the contour line of each of the identified hydrocarbon anomalies is determined. At the second stage, the boundary of the location of each zone is clarified by additional sampling. Identified anomalies are investigated by seismic methods to determine the spatial position of oil and gas deposits, to clarify their boundaries. The obtained data is then used to determine the location of the prospecting, exploratory and production wells, which significantly reduces the cost of exploration (Cl. RF No. 2177631).

A known method of geological exploration of oil and gas, as a first stage, comprising conducting gas-geochemical surveys on the studied area to study the composition of gases adsorbed on a clay matrix. According to the results of the survey, zones of hydrocarbon anomalies are identified, and then electrical exploration is carried out in sections of the area according to profiles within the identified hydrocarbon anomalies with access to a normal field. To identify surface gas anomalies genetically related to oil and gas deposits, the search area is crossed along linear profiles, samples of subsoil rocks are taken from the pits, which are laid with the calculation of opening the horizon located below the surface gas exchange zone. Subsoil clays lying on bedrock are analyzed, which provides information on the quantitative and qualitative composition of sorbed gases genetically related to hydrocarbon deposits. The rock samples taken are dried to constant weight and ground. After that, a quantitative and qualitative composition of gases adsorbed on a clay matrix is determined on a chromatographic system with thermal conductivity detectors. The system consists of two gas chromatographs CHROM-5 (ChSN-340070) and LHM-80. Analytical work is carried out according to the method of gas chromatography in isometric mode. In the process of interpreting the obtained data, gas anomalies are established at the boundaries of the oil-water and gas-oil contacts. The resulting gas anomalies reflect the gas saturation of the host rocks and the intensity of gas flows from hydrocarbon deposits. This information allows us to extrapolate the gas saturation of the rocks over the area and in the context and conclude that there is a hydrocarbon "column" (p. RF №2102781).

The disadvantage of this method is the non-standard position of the horizon located below the surface gas exchange zone. In various areas, geological conditions inherent only to them exist with fault zones, intermittent intercalation of clay and sand layers, often not only clay, but also sandstones and pebbles occur on bedrock. In this case, the flow of hydrocarbon gases can be dispersed and not fixed on the clay, which makes changes in the methodology and affects the correctness of the method.

A known method of geochemical testing of local objects in the prediction of oil content. According to the known method, a sample is taken from a clay near-surface interval of up to 5 m on a uniform object grid of 400 × 400 m by drilling holes at a training object and an object under study. Next, an analysis of the hydrocarbon gas composition of all selected clay samples (natural adsorbent) is carried out, hydrocarbon compounds from methane to hexane are studied by a chromatographic method. Quantitative and qualitative assessment of samples, calculations of background values of gas-geochemical indicators and comparison with gas-geochemical characteristics of an oil object are performed. The conclusion about the probable oil content of the investigated object is given on the basis of a comparison of the results with the indicators of the object with proven oil content (paragraph RF No. 2298816).

The disadvantage of this method is the fact that often on bedrock not only clay, but also sandstones and pebbles. In this case, the flow of hydrocarbon gases can be scattered and not fixed on the clay.

The closest to the claimed one we consider the GORE-SORBER survey method, which includes: passive collection of hydrocarbon vapors for a certain period of time using an artificially created adsorbent embedded in the soil to a depth of 60 cm, which allows it to be sorbed and subsequently detected using gas chromatography and mass spectroscopy hydrocarbon gases (C1-C5), which are used as markers of hydrocarbon sources at a depth. Geochemical modeling and interpretation is based on the chemical similarity of traces of soil gas with a known oil source (oil well) and a background gas without a source ("dry" well). According to the results of the work, the probability profile of the oil source of the geochemical anomaly is determined. [Exploration methods GORE-SORBER Exploration Surveys / American company W.L. Gore & Associates, Inc] http://www.tatneft.ru/news/nt/17-01-04.pdf.

The disadvantages of this method are a significant percentage of the loss of installed sorbers during extraction from the soil, the monopoly ownership of WLGore & Associates by an artificial adsorbent, which complicates the widespread use of this geochemical survey for preliminary assessment of oil and gas content, while the high cost of the research method forces to limit the area of exploration and increase the installation step of the modules sorbers (step of geochemical survey), which reduces the efficiency of the forecast of oil content.

The objective of the invention is to increase the efficiency of forecasting hydrocarbon deposits by gas-geochemical criteria in a region where common geological and geophysical features positively characterize the possibility of detecting oil and gas deposits.

The problem is solved by the method of predicting hydrocarbon deposits by sequential sampling of subsurface gases from a borehole at two horizons: 0.3-0.4 m and 0.8-1.0 m with preliminary sealing of each horizon from the atmosphere, while gas samples are subjected to gas-geochemical analysis for methane content and heavy hydrocarbons, and when the gas concentrations exceed their background values by at least 2 times and the concentration at the lower horizon relative to the upper one is not less than 1.5 times higher, they conclude that e hydrocarbon deposits.

To increase the reliability of the results obtained, a gas analysis is additionally carried out for the content of carbon dioxide, hydrogen, helium, oxygen and nitrogen, as well as cuttings for absorbed hydrocarbons.

The method is as follows. Based on the favorable geological and geophysical features of the possible presence of oil and gas, the study area is selected. These areas include sedimentary basins as well as other genesis, with the presence of reservoirs and tires and other features. Drill a hole to a depth of 0.3-0.4 m, the hole is sealed from the atmosphere and a gas sample is taken in the upper horizon of the subsoil. Then the hole is drilled to a depth of 1.0 m, an airtight plug is installed at a depth of 0.8 m and a gas sample is taken in the range of 0.8-1.0 m. A vacuum depression is created on both horizons to clean the gas from air impurities, after which a sample of the studied horizon is taken. In the taken gas samples, methane and heavy hydrocarbons (hydrocarbon gases (C1-C5)) are determined on a chromatograph, and, if necessary, an additional analysis of the gas is carried out for the content of carbon dioxide, hydrogen, helium, oxygen and nitrogen, as well as cuttings for absorbed hydrocarbons, which increases the reliability of the forecast. Compare the amount and composition of gas at selected horizons. If the gas composition at both horizons is close and the concentration of hydrocarbon gases exceeds the background by 2 or more times, and its amount increases from top to bottom by at least 1.5 times, this indicates a flow of gas coming from the bowels.

The interpretation of the results is carried out using probabilistic statistical methods for processing the results.

The inventive method allows to reduce the influence of modern processes of the formation of microbial methane in the upper horizons of the soil, especially in the humus layer, since the conclusion about the prospects of this region is not based on absolute concentrations of adsorbed gases, but on the analysis of the gas flow, which is determined by the ratio of the concentrations of the constituent gas components to lower and upper horizons. The main components-indicators are considered to be methane and heavy hydrocarbons, but to improve the quality of the forecast assessment, the content of carbon dioxide, hydrogen, helium, and oxygen are also taken into account. If an abnormal flow of methane and heavy hydrocarbons is detected (a background concentration is two or more times higher and the concentration at the lower level is not less than 1.5 times higher than the upper level), a positive forecast of oil and gas potential is made. At the same time, the presence of hydrogen and helium in the gas indicates a deep inflow of natural gases from the bowels, the presence of carbon dioxide characterizes the presence of intrusive rocks in the bowels, which allows a more reliable understanding of the geological structure in the study area.

The technical result of the proposed method, namely, increasing the effectiveness of the preliminary forecast for the presence of hydrocarbon deposits is achieved not only by taking into account the geological conditions of the research area and the composition and quantity of the gaseous components determined, but also by introducing the vertical analysis of the dynamics of these indicators into the analysis of the forecast. Gas samples are taken from an array of subsurface sediments at two horizons isolated from the atmosphere, which makes it possible to determine the gas flow based on a comparison of the composition and content of its components at the lower and upper horizons and avoids the influence of modern microbial gas formation processes on the analysis of the obtained results.

The gas sampling horizons were selected based on the conditions of differences in the activity of microbial activity for the formation of microbial methane. In the upper layer there is an active process of microbial production of methane, in the lower - passive. If there are anomalies in the layers and when comparing the concentrations of hydrocarbons on two layers, a conclusion is drawn about the flow of hydrocarbons from the hydrocarbon reservoir. Depending on the geological and soil conditions, the intervals are determined experimentally, as a rule, they are located at 0.3-0.4 and 0.8-1.0 m, that is, the condition is taken into account - the upper layer is microbially active, the lower one is microbial passive.

As a confirmation of the described method for predicting oil and gas potential, we present the data that were obtained as a result of surveying subsurface gases in 2000-2001 in the Bikinsky sedimentary basin, and were analyzed and confirmed in 2007.

The drawing shows the gas-geochemical scheme of the study on Bikinsky Square (scale 1: 100000). 80 gas measurements were performed on 5 profiles. An analysis of the results obtained at that time shows that, in the region of fault zones in subsoil gases, two anomalies of methane and other gases exist at two drill-hole horizons of 0.3 and 0.8 m. The methane anomaly (50 ppm) on the upper horizon (0.3 m) exceeded the background by 25 times, and on the lower (0.8 m) methane concentration exceeded the background by 50 times (100 ppm), which clearly indicates the presence of a methane stream from the bowels in this region . In addition, elevated methane concentrations were also recorded at the boundaries of the basalt covers. This allowed us to say that the hydrocarbon potential is present in the bowels of this basin and the further implementation of a complex of costly oil and gas exploration (geophysical, drilling) is positively assessed, which was confirmed by the studies conducted in 2005-2007 and a reasonable conclusion was made about the positive forecast and further drilling works in the area.

Similar results were obtained during gas-geochemical analysis in the region of the coast of Sukhodol Bay, Ussuri Bay (Primorsky Territory).

Claims (3)

1. A method for predicting hydrocarbon deposits by sampling subsurface gases and subsequent gas-geochemical analysis for the content of methane and heavy hydrocarbons, characterized in that the samples of subsurface gases are taken from the holes sequentially at two horizons - upper 0.3-0.4 m and lower 0, 8-1.0 m with preliminary sealing of each interval from the atmosphere, and when the gas concentrations exceed their background values by at least 2 times and increase the concentration in the lower horizon relative to the upper one by at least 1.5 times d of the positive forecast of hydrocarbon deposits. 2. The method according to claim 1, characterized in that it further analyzes the subsoil gas for the content of carbon dioxide, hydrogen, helium, oxygen and nitrogen. 3. The method according to claim 1, characterized in that it further conducts a gas-geochemical analysis of the cuttings for absorbed hydrocarbons.