RU2135766C1 - Process monitoring exploitation of oil fields - Google Patents

Abstract

FIELD: oil industry. SUBSTANCE: process includes conducting of geophysical and geological examinations of wells and laboratory studies of properties of pool fluids and porous media, interpretation of materials of geophysical and geological examinations, building of detail volumetric geological and hydrodynamic model of lamination-inhomogeneous pool by dismembering and correlation of sections by data of geophysical and geological examinations, determination of volumes of collected oil in production wells and volumes of pumpings in injection wells and issue of recommendations to carry out geological and technical measures. Complex of logging investigations of wells is performed additionally and local geologic-statistic sections are plotted by complex of logging curves. Adoptive approach consisting in storage of knowledge on peculiarities of geological structure of pool by way of successive transfer from exposure of global laws of change of geological and geophysical characteristics to bringing to light and registration of local peculiarities of structure is used for dismembering and correlation of sections. This base is employed to construct detailed volumetric geological and hydrodynamic model of lamination-inhomogeneous pool and hydrodynamic linkage of correlated semi-pools of adjacent wells is additionally corroborated by comparison of volumes and dynamics of pumping and intervals of perforation of injection wells and dynamics of extraction of oil and water, intervals of perforation of production wells and/or by conducting of additional studies by geophysical methods. EFFECT: enhanced authenticity and efficiency of process under conditions of complex structure of collectors. 2 cl, 6 dwg

Description

 The invention relates to the oil industry, and in particular to methods for monitoring the development of oil deposits.

 Known methods for monitoring the development of oil deposits according to the results of numerical modeling of oil displacement processes (for example [1]). This approach, implemented in the form of three-dimensional filtration models, can give an idea of the distribution of oil saturation not only in individual sections of the field, but also in the section of the oil reservoir. However, the possibilities of this approach in practice are limited due to the fact that: a) the accuracy of calculations using numerical mathematical models of development processes does not match the accuracy of the initial data (measurements are made with large errors, there is no information about many important parameters); b) maintaining deterministic permanent models of large oil fields requires a huge amount of machine time, which can lead to a loss in the efficiency of monitoring and control of oil production processes.

 A known method of monitoring the development of oil fields using maps of residual oil-saturated thicknesses [2]. The disadvantage of this control method is its low reliability due to insufficient consideration of the geological structure of the stratified heterogeneous formation and the inability to control the development of reserves along the section of the formation.

 Also known is a method of monitoring the development of oil fields according to geophysical research of wells (GIS) [3], associated with stopping the operation of the well, the use of expensive research equipment and time-consuming. This method of development control is only suitable for spot research.

 Closest to the proposed technical essence is a method for monitoring the development of oil deposits using profiles and block diagrams of reserves [4], including geophysical, geological and field studies of wells and laboratory studies of the properties of reservoir fluids and porous media, interpretation of materials from geophysical studies wells, the construction of a detailed volumetric geological and hydrodynamic model of a stratified heterogeneous formation by partition and correlation of sections according to well logging data, s accumulated volume of oil to the production wells and the volume of downloads for the injection wells and the issuance of recommendations for the geological and technical activities.

 The disadvantage of the prototype is that the known method does not sufficiently take into account the distribution of the filtration characteristics of the formation by area and section and the features of a particular field, implementing some general approaches to correlation, which reduces the reliability and efficiency of the constructed models, especially in conditions of the complex geological structure of the reservoirs.

 Therefore, in deposits having a complex structure, as well as non-parallel occurrence of productive formations, the use of a prototype can lead to unreasonable conclusions about the appropriateness of certain geological and technical measures.

 The problem and the technical result solved by the invention are to increase the reliability and efficiency of the method for monitoring the development of oil deposits in a complex reservoir structure by constructing an adequate geological and hydrodynamic model, by adapting to the geological conditions of the field, taking into account the distribution of the formation filtration characteristics by area and section and additional confirmation of the hydrodynamic connectivity of correlated layers.

 The proposed method for monitoring the development of the oil reservoir will, accordingly, ensure the effectiveness of ongoing geological and technical measures.

 The problem is solved by the fact that they additionally carry out a complex of logging studies of wells, separate and correlate sections by constructing local geological and statistical sections using a complex of log curves with tracking layers and additional correlation of sections by zones of characteristic permeabilities, use the adaptive approach to divide and correlate sections. consisting in the accumulation of knowledge about the peculiarities of the geological structure of the reservoir through a gradual transition from the occurrence of global patterns of changes in geological and geophysical characteristics to identify and take into account local structural features, on the basis of this a detailed volumetric geological and hydrodynamic model of a layered heterogeneous formation is built, additional control studies are carried out in wells located in poorly lit test sections and additionally confirm the hydrodynamic connectivity of correlated layers of neighboring wells by comparing volumes and dynamics of injection and intervals n perforation of injection wells and dynamics of oil and water extraction, perforation intervals of production wells and / or by conducting additional studies using geophysical methods, build maps of the initial and residual oil-saturated thicknesses of the formation, identify the produced oil-saturated thicknesses within the framework of the detailed geological and hydrodynamic model constructed, build profiles and block diagrams of stockpiling.

 Using the adaptive approach of the correlation process, the correlation process is divided into two main stages, at the first of which, by examining the entire set of well sections in different directions, various patterns of the prevalence of reservoirs, supporting well correlated clay layers, changes in thickness, inclination angles, and a number of other parameters over the area are revealed and section; at the second stage, re-correlation is carried out taking into account the available information and accumulated knowledge, and the uncertainties arising from this are resolved by using the data collected in the first stage.

 To confirm the hydrodynamic connectivity of the correlated layers, the production and / or injection wells of the most ambiguously identified layers are perforated.

 A comparative analysis of the essential features of the proposed technical solution and prototype allows us to conclude that the claimed invention meets the criterion of "novelty." A significant difference from the prototype is the construction of local geological and statistical sections using a complex of logging methods (standard logging, radioactive logging, etc.) and the use of the adaptive correlation method, which allows you to select automatic correlation parameters when comparing well sections in accordance with the peculiarities of the geological structure of this particular field, on the basis of which an adequate volumetric geological and hydrodynamic model of the oil reservoir is built, profiles and block diagrams swelling of oil-saturated thicknesses. The proposed correlation method formalizes the set of data characterizing the geological structure of the reservoir. Its use is effective in conditions of complex oil fields with non-parallel occurrence of reservoirs or in reservoirs with a clear areal zonation (pronounced lithologic facies sections), when the available methods of automatic correlation [4, 5] cannot take into account the nature and prevalence of structural variability and heterogeneity layer. The profiles and block diagrams of the production of oil-saturated thicknesses, built on the basis of the revealed features of the geological and hydrodynamic model, serve as a reliable basis for the operational control and management of oil field development processes. A comparison of injection volumes and dynamics, injection perforation intervals and oil and water withdrawal dynamics, production well perforation intervals allows us to confirm the hydrodynamic connectivity of correlated layers, which serves as an additional justification for the correctness of the chosen geological and hydrodynamic model. If necessary, perforation of production and / or injection wells is carried out for this.

 One of the approaches to the problem of automatic correlation is, as you know, the construction of geological and statistical sections (GSR), proposed by V. A. Badyanov [5]. GSR refers to the probability of depth distribution of reservoirs within a selected area of a field.

 Under the conditions of unstable sedimentation, facies variability of deposits over the area of the field, the choice of areas for the construction of geological exploration significantly affects the type of geological and statistical section.

в интервале пласта и по среднему отклонению в этом же интервале (σ). Например в j-й скважине на глубине i значение кривой вычисляется

Таким образом в каждой скважине для кривой в интервале построения локального осредненного разреза ее среднее значение будет равняться

= 0, а стандартное отклонение σ_j = 1. Это позволяет рассматривать кривые в стандартизированном масштабе и удобной для анализа форме.Under these conditions, it is effective to use GIS methods for constructing average statistical sections (for example, curves of the relative anomaly of spontaneous polarization (PS)) [6]. The difference between the proposed method for constructing the average statistical section is that for this, the curves of several GIS methods are taken, each of which is normalized by the average value of the curve

in the interval of the reservoir and the average deviation in the same interval (σ). For example, in the j-th well at a depth i, the value of the curve is calculated

Thus, in each well for a curve in the interval of constructing a local averaged section, its average value will be

= 0, and the standard deviation σ _j = 1. This allows us to consider the curves in a standardized scale and convenient for analysis.

 The authors propose to carry out automatic correlation with preliminary adaptation, which allows you to select the correlation parameters to the features of the geological structure of this particular field. According to this scheme, the correlation process is divided into two main stages.

At the first stage, by examining the entire set of well sections in various directions, the following regularities are revealed: patterns of reservoir prevalence over the area and in the section, the nature of the change in the total and effective thicknesses over the area, the tilt angles of the packs of productive formations and mature clay interlayers in different parts of the productive area, and a number of other parameters by area and section. This is achieved by:
For each well of a pre-selected profile in all several directions, additional profiles are selected, for each of which statistical sections are built.

где

m - количество значений по глубине,
n - количество скважин,
Данная функция показывает степень упорядоченности осредненного разреза.Each such constructed statistical section is characterized by its value of some function

Where

m is the number of values in depth,
n is the number of wells,
This function shows the degree of ordering of the averaged section.

 Function (2) is calculated for one type of curve, but you can obviously use a complex parameter for several curves, and each type of curve is assigned its own weight, selected depending on how this type of log characterizes the lithology of the formation.

 Given a critical value (2), for a given well, a series of wells can be identified by the profile for which the value of function (2) does not exceed the critical value. A set of wells in profiles in various directions will allow us to identify a certain area within which the averaged section will have the most regular, nonrandom appearance.

 The next step is the construction of geological survey within the selected areas for each well of the considered profile.

 A joint analysis of the aggregate of constructed geological surveys by profile allows us to identify the most seasoned clay interlayers and the nature of their occurrence over the area. In parallel, in the same way, you can determine other characteristics of the geological structure, reflecting the global, regular features of the structure.

 This is the acquaintance with the deposit and the accumulation of knowledge.

 At the second stage, a repeated correlation is carried out taking into account the available information and accumulated knowledge. Uncertainties arising from correlation of sections of neighboring wells are resolved by using the data collected in the first stage, presented in the form of slope angles and the nature of occurrence of aged clay bridges along which the interlayers are correlated. One of the criteria for the correctness of correlation can be an increase in the degree of correlability for sections constructed taking into account the adaptive approach. The result of this step is a detailed correlated section with tracking of all interlayers.

 As for the "inventive step", the authors for the first time for the automated construction of detailed volumetric models of the current reserves development, allowing to quickly monitor the current structure of reserves and control the development of complex oil fields, proposed a new approach that takes into account the peculiarities of the geological structure of this field. A distinctive feature associated with the preliminary adaptation of the correlation process to the field conditions and confirmation of the hydrodynamic connectivity of the correlated layers of neighboring wells is new. Therefore, the proposed solution meets, in our opinion, the criterion of "inventive step". In general, the proposed technical solution improves the reliability, reliability and effectiveness of the method of monitoring the development of oil deposits.

 The method is carried out by the following sequence of operations.

 1. Conducting geophysical, geological and field studies of wells, including an additional set of well logging studies, and laboratory studies of the properties of reservoir fluids and porous media.

 2. Interpretation of GIS materials using the mathematical apparatus of Kendal statistics.

 3. Construction of local geological exploration using a set of logging curves for geophysical research methods in various areas and directions, revealing the characteristics of the geological structure of the studied area, data on the nature and angle of occurrence of aged clay interlayers, as well as the nature of their change in area.

 4. Construction of a detailed volumetric geological and hydrodynamic model of a layered heterogeneous formation: a) repeated correlation of sections by construction of local geological surveys using a complex of logging methods for geophysical surveys with the use of additional information collected in the previous stage in the form of direction and angle of inclination of interbeds, variability of properties according to area; b) the implementation of the correlation of sections along the zones of characteristic permeability.

 5. Additional confirmation of the hydrodynamic connectivity of correlated layers of neighboring wells by comparing the volumes and dynamics of injection and intervals of perforation of injection wells and the dynamics of oil and water extraction, intervals of perforation of production wells or by additional studies using geophysical methods. Conducting additional control studies in wells located in dimly lit representative measurements of control measurements.

 6. The selection of representative areas with characteristic geological and filtration characteristics and analysis of accumulated information, including control studies of wells.

 7. Construction of maps of initial and residual oil-saturated thicknesses taking into account the results of all studies.

 8. Within the framework of the detailed volumetric geological and hydrodynamic model of the reservoir constructed, identification of the developed oil-saturated thicknesses with interlayers belonging to zones of increased permeability is carried out.

 9. The construction of profiles and block diagrams of the development of oil reserves, which are used to judge the change in the nature of the development of a layered heterogeneous formation by area and section.

 10. Issuance of recommendations for geological and technical measures.

An example of a specific implementation of the method for monitoring the development of a layered heterogeneous formation according to profiles and block diagrams of the production of oil-saturated thicknesses
To prove the compliance of the claimed invention with the criterion of "industrial applicability" we give a specific example of the implementation of the method of monitoring the development of oil deposits.

Example. A method for monitoring the development of oil deposits by constructing a geological and hydrodynamic model of formation BS _{10 of the} Sredne-Balykskoye field using the adaptive correlation method for well sections.

As a result of geophysical, field research of wells and laboratory studies of the properties of reservoir fluids and porous media, interpretation of GIS materials using the Kendal statistics apparatus, a GIS database for the BS ₁₀ formation of the Sredne-Balykskoye field was created, including the relative and absolute marks of the roof and thickness of the interlayers, specific reservoir electrical resistance, spontaneous polarization potential, lithology and saturation pattern of reservoir interlayers, calculated coefficients istosti, permeability, and initial oil saturation interlayers.

Local geological surveys were constructed using a set of logging curves for geophysical research methods (PS, natural radioactivity and apparent resistance) in various areas and directions, for which more than 200 profiles were automatically stretched along the BS ₁₀ reservoir in the Sredne-Balyksky field in different directions, the analysis of which allowed to reveal the following characteristics of the geological structure of the studied area: a decrease in the total thickness from east to west, a gradual regular decrease in the thickness of the reservoirs to the south, the inclination angles of the formation with depth, the inclined occurrence of the most characteristic well-correlated clay interlayers with a fall to the west.

 A detailed volumetric geological and hydrodynamic model of a layered heterogeneous formation was constructed: a) by repeated correlation of sections by constructing local geological surveys using a set of logging methods for geophysical studies using additional information collected at the previous stage in the form of direction and inclination angles of the interlayers, variability of properties over the area; b) the implementation of the correlation of sections along the zones of characteristic permeability. So in FIG. 1 shows a paleological profile along the well line 3056-3037-2066b-2067-2126-3311-3030-2000-1176r-2068-3031-2095, the correlation of which was carried out according to the prototype method, and figure 2 shows the same profile built in the framework of the presented approach. As can be seen, when correlating with the developed adaptive approach, the previously revealed slope of the characteristic clay interlayers was taken into account, which made it possible to increase the degree of correlability of the interlayers. Correlation of reservoir sections along individual profiles without preliminary adaptation led to the artificial replacement and pinching of reservoir rocks.

 According to the development history, well 3030 entered into operation 11.85 g, accumulated oil in the well as of 02/01/98 g amounted to 72.3 thousand tons, accumulated liquid - 215.5 thousand tons. The water cut for this period was 96%. The well is currently idle. To further confirm the hydrodynamic connectivity of the correlated layers, and thus to establish the correctness of the adopted geological and hydrodynamic model, it was recommended to perforate, pump water, and 2000 in the well 3030 in the range of a.o.2439.9-2449.5 m perforate interval a.o. 2403.3-2413.9 m and conduct research on the volumes and dynamics of the extracted products. Changes in water injection volumes in well 3030 will affect production volumes and water cut in well 2000, which will confirm the hydrodynamic interconnection of the interlayers.

.Maps of the initial and residual oil-saturated thicknesses were constructed taking into account the results of all the studies performed. Figure 3 shows a map of the residual oil-saturated thicknesses of the northern part of the BS ₁₀ formation of the Sredne-Balykskoye field, constructed as of December 1, 1997. Lines show the location of the profile and block diagram. On the map, injection wells are marked with "+", producing -

.

 The worked out oil-saturated thicknesses with interlayers belonging to zones of increased permeability were identified in the framework of the constructed detailed volumetric geological and hydrodynamic model of the reservoir.

 A profile is constructed (Fig. 4) and a block diagram (Fig. 5) of oil reserves development, from which it can be seen that it is possible to solve both the problem of detailed correlation with tracking all layers along the area of the studied area, and the task of a detailed analysis of the current reserves development, and building a block diagram is actually a three-dimensional model of the productive stratum. FIG. 6 shows the conventions for FIG. 1, 2, 4, 5.

It can be seen from the above results that the upper part of the BS ₁₀ layer is uniformly developed at the field, which is represented by sustained thick thicknesses, with good reservoir properties. In most wells, the upper part has already been practically developed, however, in the middle part of the BS ₁₀ formation there are zones with undeveloped oil-saturated thicknesses separated from the upper part by an oblique clay bridge. So, as a result of the analysis of such zones, it is recommended to provide for sidetracking in the well 3032 in the direction of the well 2633 and the opening of the middle part of the BS ₁₀ formation, separated from the upper clay bridge.

 Thus, the developed system for the automated construction of geological and hydrodynamic models of a field development object based on adaptive correlation methods allows you to quickly monitor the current structure of reserves and, thereby, plan geological and technical measures for the recovery of residual oil.

 The proposed method for monitoring oil deposits turns out to be more reliable and reliable than the prototype under conditions when the geological structure of the field is the result of formation of reservoirs in various, often changing sedimentation conditions, as well as with non-parallel occurrence of reservoirs and, therefore, allows more efficient control of the development of these fields. Uses available geophysical and laboratory equipment and personal computers.

Used sources:
1. RF patent N 2055981, E 21 V 43/20.

 2. Kolganov V.I., Chashel A.G. Control over the development of oil deposits using maps of residual oil-saturated thicknesses. Oil industry.-1997, N 1, pp. 40-42.

 3. Koshlyak V.A., Sultanov T.A. The study of oil recovery by methods of field geophysics.-M: Nedra, 1986, 193 p.

 4. Khairetdinov N.Sh., Andreev V.E., Belousov N.A. Report on agreement 35.91: Development of algorithms and programs for improving the GEOPAK system in the direction of analysis of oil reserves. NPO Soyuznefteotdachka .- Ufa: 1991.

 5. Telishev A. G., Badyanov B. A., Bohan T. A. Report on research work: Creation of an automated system for calculating oil reserves in terrigenous reservoirs (final). Theme 02.81 Tyumen: SIBNIINP, 1985.

 6. Borisenko 3. G. Technique for the geometrization of reservoirs and oil and gas deposits-M .: Nedra, 1980, 206 p.

Claims (3)

1. A method of monitoring the development of oil deposits, including conducting geophysical, geological and field studies of wells and laboratory studies of the properties of reservoir fluids and porous media, interpretation of materials from geophysical studies of wells (GIS), building a detailed volumetric geological and hydrodynamic model of a layered heterogeneous formation by partitioning and correlation of sections according to GIS data, determination of the volume of accumulated oil production for producing wells and injection volumes for injection wells and the issuance of recommendations for conducting geological and technical measures, characterized in that they additionally carry out a complex of logging studies of wells, separate and correlate sections by constructing local geological and statistical sections by a complex of log curves with tracking interlayers and additional correlation of sections along zones of characteristic permeabilities, for separating and section correlations use an adaptive approach consisting in the accumulation of knowledge about the features of the geological structure of the plaz that through a gradual transition from the identification of global patterns of changes in geological and geophysical characteristics to the identification and consideration of local structural features, based on
To do this, a detailed volumetric geological and hydrodynamic model of a layered heterogeneous formation is built, additional control studies are carried out in wells located in poorly lit test sections and additionally confirm the hydrodynamic connectivity of the correlated layers of neighboring wells by comparing the volumes and dynamics of injection and intervals of perforation of injection wells and oil production dynamics and water, perforation intervals of production wells and / or by conducting additional studies using geophysical methods, build maps of the initial and residual oil-saturated thicknesses of the formation, identify the developed oil-saturated thicknesses within the framework of the detailed geological and hydrodynamic model constructed, build profiles and block diagrams of reserves development.  2. The method according to claim 1, characterized in that, using the adaptive approach of the correlation process, the correlation process is divided into two main stages, in the first of which, by examining the entire set of well sections in different directions, various patterns of the distribution of reservoirs supporting well correlated clay interlayers are revealed , measurements of thicknesses, tilt angles and a number of other parameters by area and section, at the second stage they re-correlate already taking into account the available information and accumulated knowledge and Nick thus involving uncertainty allow data collected in the first step.  3. The method according to claim 1, characterized in that to confirm the hydrodynamic connectivity of the correlated interlayers, the production and / or injection wells of the most ambiguously identified interlayers are perforated.

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