RU2085975C1 - Method for estimation of development regions of secondary collectors in basement - Google Patents

Abstract

FIELD: oil industry. SUBSTANCE: method involves geologic and geodesic investigations in bores, detection of most probable genesis of secondary collectors using petrologic investigations, detection of petrologic types and speed of spreading longitudinal waves in detected types and in secondary collectors, detection of seismic horizon between reflection of bottom of sediment jacket and reflection in upper side of basement, detection of interval between reflected waves which limits detected horizon. Areas of most probable growth of secondary collectors are judged as zones of maximal intervals. EFFECT: search and estimation of oil and gas supplies in secondary collectors. 2 dwg, 1 tbl

Description

 The invention relates to geology and can be used to search for hydrocarbon deposits in the basement under the sedimentary cover of the plate, as well as for the quantitative assessment of oil and gas reserves contained in secondary reservoirs.

A known method for predicting reservoir rocks in the roof of the foundation, including the interpretation of changes in the time interval between reflections in the basal part of the sedimentary cover [1]
The disadvantage of this method is that on its basis the binding of reflecting boundaries is incorrectly performed and the allocated basal terrigenous reservoirs are actually secondary collectors (VC), which are developed not in the bottom of the sedimentary cover, but in the foundation. To confirm the mechanism of reservoir formation and the correct binding of reflecting boundaries at seismic time sections, lithological and petrophysical core studies are required.

The closest technical solution, taken as a prototype, is a method for predicting development zones of VC in the foundation, including the interpretation of seismic reflected waves attached to the bottom of the sedimentary cover and underlying acoustic boundaries, taking into account the data of geological and geophysical studies in wells [2]
The disadvantage of the method adopted as a prototype is its low reliability, due to the fact that only weathering crusts are considered as VCs, and geological and geophysical studies in wells are concentrated on identifying their properties.

 It is known that weathering crusts are composed mainly of clay minerals, sesquioxides and hydroxides that have low filtration and capacitive properties and therefore cannot be reservoirs and contain hydrocarbon deposits.

 To confirm the formation mechanism of the reservoir, as in the analogue, lithological and petrophysical studies of core samples are required, and it is also necessary to link the reflecting boundaries inside the foundation to clarify the lower boundary of the VC distribution and the phase state of the fluids saturating it.

 The objective of the invention is to increase the reliability of the method for predicting zones of development of VC.

 The task is achieved by the fact that in the known method for predicting development zones of VC in the foundation, including the interpretation of seismic reflected waves attached to the bottom of the sedimentary cover and one underlying acoustic boundary, taking into account the data of geological and geophysical studies in wells, lithological and petrophysical studies are carried out, with the help of which determine the most probable genesis of secondary reservoirs, on the basis of which lithotypes are distinguished, by which secondary collectors are formed, and the area is determined once the flow of these lithotypes within the considered field, they determine the propagation velocity of longitudinal waves in the identified lithotypes and in secondary collectors developing along them, distinguish a seismic horizon between the reflection from the bottom of the sedimentary cover and the reflection in the roofing of the foundation, taking into account the obtained lithological-petrophysical and velocity characteristics, conduct quantitative interpretation of changes in the time interval between the reflected waves, limiting the selected seismic horizon, and the zone of maximum int Time intervals are considered as areas of the most probable development of secondary reservoirs.

 In FIG. Figure 1 shows a temporary seismic section passing through the borehole and its lithological-stratigraphic section corresponding to the interval of occurrence of the seismic horizon K between the upper K1 reflecting boundary and lower A reflecting boundary, including additional reflection A1, where 1 clay, 2 coals, 3 secondary reservoir (hydrothermal silicites ), 4 calcareous schists, 5 gas, 6 gas-oil transition zone, 7 oil, 8 — location in the temporal section of the litho-stratigraphic column shown to the right of it, 9 discontinuous violations.

 In FIG. Figure 2 shows the location of the projected areas for the development of secondary reservoirs, where 10 are the predicted development zones of the VC, 11 is the location of the wells, 12 is the area of distribution of potentially productive lithotypes (PPL).

 The method is implemented as follows.

 Seismic surveys are carried out on the selected area. According to the drilling data and the results of geophysical studies of well logs), reflecting boundaries are mapped on temporary seismic sections, the bottom of the sedimentary cover is composed mainly of clay minerals that reliably screen hydrocarbon deposits in the secondary reservoirs in the basement.

 Seismic horizon K is distinguished in the foundation, limited from above by reflection from the bottom of the sedimentary cover, and from below by reflection in the roofing part of the foundation.

 The time interval between the reflecting boundaries K1 and A is determined, which corresponds to the seismic horizon K and is called for brevity its temporal power (see FIG. 1).

 On time sections, sections are identified within which the seismic horizon K has a larger temporal power compared to neighboring ones, as well as intervals where an additional reflection A1 appears inside these sections with increased time power (Fig. 1).

 Based on the results of field tests and well logging data, the phase state of hydrocarbons is established in secondary reservoirs located in horizon K.

 Lithological-mineralogical and petrophysical studies of core samples are carried out; according to these studies, the reservoir genesis in the basement is reconstructed. To do this, collector properties are compared with the material composition of the source rocks, which form the foundation and develop on them as a result of secondary processes of (altered) rocks.

 Based on the analysis of the lithological and reservoir properties of the basement rocks, lithotypes are established, due to which the most capacious VCs appear, which is explained by the peculiarities of their composition (easy solubility and removal of unstable components, as well as a strong mineral skeleton that prevents compaction of the resulting VC). Highlighted lithotypes are called potentially productive lithotypes (PPLs).

 Based on the conducted lithological and reservoir studies, a conclusion is drawn on the formation mechanism of VC and the type of collector.

 According to the data of drilling, lithological and petrophysical studies and the results of the interpretation of the well log data, the area of PPL development in the foundation is established, which corresponds to the seismic horizon K in the time sections of the study area.

 Then, the acoustic properties of PPL in kerosene-saturated are determined, and VK formed in them in kerosene and gas-saturated states. Kerosene saturation simulates oil saturation. Determinations are carried out under conditions simulating reservoir temperatures and pressures. Set the bulk density of the PPL and VK.

(см. И. И. Гурвич, Г.И. Боганик. Сейсмическая разведка, М. Недра, 1980, с. 67), Определяют коэффициент отражения Ap на границе между газо- и керосинонасыщенными ВК, где d₁ и d₂ плотности граничащих пород, а Vp₁ и Vp₂ скорости распространения в них продольных волн.According to the well-known formula

(see I.I. Gurvich, G.I. Boganik. Seismic exploration, M. Nedra, 1980, p. 67). The reflection coefficient Ap is determined at the interface between gas and kerosene saturated VK, where d ₁ and d _{2 are} densities bordering rocks, and Vp ₁ and Vp ₂ the propagation velocity of longitudinal waves in them.

 It is well known that with Ap values of 0.1 and higher, a stable reflection is formed from the boundary of the objects under consideration. Therefore, if the Ap values calculated at the boundaries between gas-and oil-saturated VCs are equal to or greater than 0.1, then it is believed that the additional reflection A1 present in the seismic horizon K in areas with increased temporal power corresponds to the gas-liquid phase boundary.

 It is determined how many times the increase in the temporal thickness of the horizon K occurs in comparison with the neighboring (with unexpanded thickness) sections and correlate the magnitude of this increase with the change in the velocity of propagation of longitudinal waves in the initial SPL and VC developing along them. Areas with a proportional increase in the temporal power of the seismic horizon K correspond to the predicted zones of the development of the VC in the submarine.

 Areas with increased temporal thicknesses of the seismic horizon K highlighted in time sections are mapped. The resulting map with highlighted sections of the predicted VC is used to select the locations of the first exploration and then production wells.

 Using the obtained data on the area and power of VC, as well as on the nature of their saturation, an assessment is made of the hydrocarbon reserves contained in them.

 Example. The effectiveness of the proposed method was verified by predicting the zones of development of secondary reservoirs in the foundation (pre-Jurassic complex) of the plate of the North Varyegan field, which was carried out on the basis of combining the results of the areas of seismic exploration with data from drilling, well logging, lithological and petrophysical and (additional) acoustic studies of core samples.

 On-site seismic exploration of OGT was carried out within the field. According to drilling and well logging data, the reflecting boundaries were referenced at temporary seismic sections, the bottom of the sedimentary cover, composed mainly of carbonaceous clay periods and being a reliable fluid support, was identified, as well as the continuously reflecting boundary immediately below it, due to a change in the lithological composition of the rocks in the roofing part of the foundation ( contact between siliceous limestones (above) and calcareous schists (bottom) [Fig. 1, item 4).

 A seismic horizon K was identified in the roofing part of the foundation, limited above by the reflection K1 arising on the boundary between the bottom of the sedimentary cover represented by carbonaceous-clay deposits of the Lower Jurassic and the roof of the foundation, and from the bottom by the nearest continuous reflection A in the roofing part of the foundation, arising on the border of siliceous limestones and clayey shales of lower carbon age (figure 1).

 In time sections, sections were identified within which the seismic horizon K has an increased temporal power compared to neighboring sections, as well as intervals where an additional reflection A1 appears inside these sections with increased time power (Fig. 1).

 Core samples were taken from exploratory wells, and then their lithological and petrophysical studies were carried out.

 Using the data obtained from lithological and petrophysical studies of core samples, the reservoir formation mechanism in the foundation was reconstructed. To do this, the reservoir properties and the material composition of the initial rocks were compared, which compose the roofing part of the foundation and develop on them as a result of secondary processes of (altered) rocks.

 Based on the analysis of the lithological and reservoir properties of the rocks that make up the roofing part of the foundation of the Severo-Varyoganskoye field, it was established that the highest-grade VCs arise from siliceous limestones, which is explained by the features of their composition (easy solubility and removal of carbonate material, as well as a strong silicon cage that prevents compaction of the resulting VK). This lithotype was attributed to PPL.

 It was determined that silicites originating from the initial siliceous limestones and named after the high content of silica in their composition (up to 95%) have a porosity of up to 34% and a permeability of up to 295 fm2. By the presence in their composition of such intervals as sericite, dikkit, and spherosiderite, which are not found in the initial siliceous limestone, as well as by the absence of minerals such as calcite, dolomite, feldspars, pyrite, and organic matter, which are obligatory components of the initial siliceous limestones, were established hydrothermal mechanism of their formation under the influence of medium temperature, acidic fluids. This is also evidenced by the recrystallization of the original cryptocrystalline biogenic silica contained in siliceous limestones into finely crystalline well-faceted quartz, which makes up the bulk of hydrothermal silicates (up to 95%).

 Based on the studies, it was found that the voidness in hydrothermal silicites belongs to the fissure-pore-cavernous type and arose mainly due to the dissolution and removal of carbonates (calcite and dolomite). Hydrothermal silicites were attributed to VK.

 It was determined that in other lithotypes, for example, shales that are part of the roofing of the pre-Jurassic complex, despite the hydrothermal effect, the formation of a secondary collector does not occur, which is explained by the low content of dissolved components (carbonates) in them, as well as their high ductility, which prevents conservation emerging secondary porosity.

 Therefore, according to the data of drilling, lithological and petrophysical studies of the core and the results of the interpretation of well logs, the area of distribution of siliceous limestones in the roofing of the pre-Jurassic complex of the North Varyegan field was determined (Fig. 2, item 12).

 On the example of well 2P, according to the test data and well logging, the phase state of hydrocarbons in the secondary reservoir was established. The upper part of the reservoir is filled with gas, in the middle a transitional gas and oil zone and the lower part is oil-saturated (Fig. 1, pos. 5, 6 and 7).

 Core samples were taken from the basement, represented by hydrothermal silicites and siliceous limestones. Cylinders with a diameter of 40 mm and a height of 16 mm were cut from samples. By the standard method, the reservoir properties of cylindrical samples and their bulk density were determined. On the acoustic installation PIVK-1, the propagation velocity of longitudinal waves Vp in them was measured on the same samples under conditions simulating reservoir.

 When determining the speed characteristics of samples of hydrothermally altered reservoir rocks, they were saturated with both kerosene (oil saturation modeling) and air (gas saturation modeling).

 The results of determining the speed characteristics of various lithotypes of basement rocks in both kerosene-saturated and gas-saturated states, as well as their densities and reflection coefficients calculated on their basis, are given in the table.

 It was determined that the propagation rate of Vp in hydrothermal silicites in the kerosene-saturated state is less than 1.1-1.7 times in unchanged siliceous limestones, and in the gas-saturated state 1.4–1.2 times. According to this criterion, it was accepted that the sections on temporary sections, where the temporal thickness of the horizon K increases by more than 1.25 times compared to neighboring intervals, are represented by altered reservoir rocks (hydrothermal silicites), (Fig. 2 and table). On average, the temporal thickness in the intervals of hydrothermal silicites development compared to the thickness of the initial siliceous limestones, according to acoustic studies, increases 1.7 times.

 It is generally accepted that at Ap values of 0.1 or more, a reflection is formed that is recorded in the time section. It follows from the table that Ap at the boundary of the change in the phase state of the reservoir fluid (gas-liquid) in hydrothermal silicites in the roof of the pre-Jurassic complex is 0.2 (table). This value is higher than the accepted critical value, equal to 0.1, therefore, at the phase boundary, reflection A1 is formed inside areas with increased temporal power of the seismic horizon K (Fig. 1).

 Using data from field trials and well logging as an example of SLE. 2P checked the correspondence of the additional reflection A1 in the area with increased time power of the seismic horizon K to the gas-liquid phase boundary (Fig. 2).

 According to certain criteria, namely: on the area of development of siliceous limestones in the roof of the foundation, overlain by reliable clayey fluid support to increase the temporal thickness of the seismic horizon K by more than 1.25 (1.7 times on average) compared with its minimum values, the predicted zones of development of secondary reservoirs in the roof of the pre-Jurassic complex, according to the additional reflection A1 in areas with increased time power of the seismic horizon K, established a two-phase state of the pore fluid. The obtained zones of the alleged distribution of secondary reservoirs of hydrothermal origin were mapped (figure 2).

 Using the data obtained, hydrocarbon reserves in hydrothermal silicites were estimated.

 The reliability of the method was checked on the available time sections and the results of lithological and petrophysical core studies and field tests on 12 wells drilled within the selected area of the North Varyegan field. In 11 of 12 wells, the forecast was confirmed, which corresponds to almost 92% of the forecast success.

Claims (1)

 A method for predicting the development zones of secondary reservoirs in the foundation, including the interpretation of seismic reflected waves attached to the bottom of the sedimentary cover and one underlying acoustic boundary, taking into account the data of geological and geophysical studies in wells, characterized in that they carry out lithological and petrophysical studies, which determine the most the probable genesis of secondary reservoirs, on the basis of which lithotypes are distinguished by which secondary reservoirs are formed, and the area p Situations of these lithotypes within the field under consideration determine the propagation velocity of longitudinal waves in the identified lithotypes and in secondary collectors developing along them, distinguish a seismic horizon between the reflection from the bottom of the sedimentary cover and the reflection in the roofing of the foundation, taking into account the obtained lithological-petrophysical and velocity characteristics, conduct quantitative interpretation of changes in the time interval between the reflected waves bounding the selected seismic horizon and the zones of maximum and Tervala time is considered as the most probable areas of secondary collectors.

Images