RU2451177C1 - Control method of formation development - Google Patents

Abstract

FIELD: oil and gas production.

SUBSTANCE: seismic exploration operations, well geophysical researches and core lab researches are carried out. According to core lab researches and well geophysical researches data there revealed are interrelations of formation filtration reservoir characteristics and reference logs. Formation structures are revealed by summarised data of seismic exploration operations and well geophysical researches. Formation filtration reservoir characteristics and relative position of parts comprising the formation are defined on the basis of widespread reference logs in interwell space of unexamined formation areas and obtained interdependence of formation filtration reservoir characteristics and reference logs. Note that in the course of well geophysical researches additionally there performed is at least one type of logging. Note that additional logging is done in any well. Formation filtration reservoir characteristics and relative position of formation parts are defined by means of confirmed Fourier analysis of changing of all obtained reference logs in interwell space.

EFFECT: improvement of determination accuracy of formation filtration reservoir characteristics and relative position of parts comprising the formation.

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Description

The invention relates to the oil industry, namely to study the structure of the reservoirs to control the development and to optimize the location of production wells in the studied field, in particular, to methods for evaluating the filtration flows formed during the development of oil fields.

A known method of monitoring the development of reservoirs, in particular, for placing wells according to the results of a study of the reservoir structure (prototype [1]), based on the inter-well distribution of log curves, including seismic surveys, geophysical surveys in the entire interval of the reservoir perpendicular to the formation of wells, laboratory studies cores, identification of the core data of laboratory studies of cores and geophysical studies of wells of the interdependence of filtration-capacitive characteristics IR reservoir and well logs, and reservoir building structures based on the above data. Determine the reservoir properties of the reservoir and the relative position of the parts making up the reservoir based on the well logs common in the interwell space and the revealed interdependence of the reservoir properties of the reservoir and the logs. Logging diagrams corresponding to one physical field are distributed into the interwell space by analyzing the change in the shape of the logging diagram over the entire interval of the formation along strike, taking into account the geological variation of the formation along strike. Control over the development and, in particular, recommendations for the location of the wells are carried out according to the obtained reservoir properties of the reservoir, through hydrodynamic modeling. The effectiveness of the prototype is confirmed by the consistency of the predicted and actual well logs.

The prototype method is not effective enough, since it involves only one type of logging (which, however, corresponds to the practice of well logging); accordingly, the reservoir properties of the formation are not determined reliably enough. At the same time, the reservoir properties of the reservoir are the basis for monitoring the development and, in particular, the placement of production wells.

The task at hand is to increase the reliability of control over the development of reservoirs, including increasing the reliability of the justification for the location of production wells.

The technical result is reliably determined reservoir characteristics of the reservoir and a reliably defined relative position of the parts making up the reservoir, increasing the reliability of field development monitoring and drilling performance, reducing the risks of incorrect estimation of technological parameters when constructing geological and hydrodynamic models. Moreover, the determination of reservoir properties of the reservoir is carried out through the coordinated use of logs corresponding to more than one type of physical field, including those conducted in addition to the standard well logging set and not necessarily in all wells.

The problem is solved in that the proposed method for monitoring the development of reservoirs, including seismic surveys, geophysical surveys of wells, laboratory studies of core samples, identifying, based on the totality of data from laboratory studies of core samples and geophysical surveys of wells, the interdependence of reservoir and reservoir characteristics and logging diagrams, identifying the totality of data seismic surveys and geophysical studies of wells of the reservoir structure, determination of filtration-reservoir the distinct characteristics of the reservoir and the relative position of the parts that make up the reservoir, based on the common logs in the interwell space of unexplored sections of the reservoir and the revealed interdependence of the reservoir properties of the reservoir and logs, is characterized in that at least, additionally, during the geophysical studies of the wells, one more type of logging, moreover, additional logging is carried out on any well, and the reservoir properties of the reservoir and mutual memory location portions of the formation is determined by Fourier analysis agreed changes of all the received logs in the inter-well space.

Thus, according to the claimed method, it is not necessary to carry out the same complex of geophysical surveys of wells in all considered wells. The applicant is also aware of other technical solutions, for example [2], where several types of logging are used, but for their quantitative interpretation when determining the reservoir properties of the reservoir, all of these several types of logs should be logged in all studied wells. Therefore, the distinguishing feature of the proposed method relating to additional logging at any well is new and provides, in the claimed combination of features, the inventive step of the method.

The proposed invention is implemented by the following sequence of operations.

1. Conduct seismic surveys.

2. Conduct geophysical surveys of wells (GIS) to obtain well logs corresponding to at least two physical fields; and an additional type of logging is carried out in any well and regardless of the location of the wells.

3. Conduct laboratory tests of cores.

4. By the totality of the data of laboratory research of cores and geophysical research of wells, the interdependence of the filtration-reservoir characteristics of the formation and the shape of the log diagrams of each type are revealed.

5. Construct a reservoir structure based on data from seismic surveys and geophysical surveys of wells.

6. Identify the characteristic shape of each log diagram characterizing each physical field on each investigated well of the reservoir under study, by representing the log curves ξ (x, y, z) in the form:

- ортонормированный базис, ψ(x, y, z) - «шум», N - количество членов в разложении Фурье по базису

. Вопрос выбора N, в каком-то смысле вопрос экспертной детализации, сопряжен с некорректностью задачи восстановления каротажных диаграмм рядом Фурье. В заявленном способе N выбирается из физического принципа, а именно, энергетическая составляющая суммы ряда равна, с определенной точностью, энергии входной кривой ξ(x, y; z).here (x, y) are the coordinates along the strike, z is the vertical component,

is the orthonormal basis, ψ (x, y, z) is “noise”, N is the number of terms in the Fourier expansion of the basis

. The question of choosing N, in a sense, the question of expert detailing, is fraught with the incorrectness of the task of reconstructing logs near the Fourier series. In the claimed method, N is selected from the physical principle, namely, the energy component of the sum of the series is, with a certain accuracy, the energy of the input curve ξ (x, y; z).

The obtained characteristics of the logs in the form of the coefficients (a ₀ (x, y), a ₁ (x, y), ...) of the decomposition of the logs according to the Fourier basis allow us to fairly objectively characterize the formation.

7. Logging diagrams characterizing the physical fields in the wells are consistently distributed into the interwell space along the strike of the formation by interdependently reproducing the decomposition coefficients of logging diagrams of the form (1) for different types of well logs.

Since the interdependence of the decomposition coefficients of logging diagrams of different types is taken into account, logging diagrams characterizing different physical fields in wells do not have to be pairwise known in all considered wells. As a result, the complementarity of logging diagrams of various types is ensured, which, in turn, leads to a significant improvement in the quality of determining the reservoir properties of the reservoir and thereby increases the reliability of monitoring the development and placement of production wells planned for drilling.

8. Determine the reservoir properties of the reservoir and the relative position of the parts that make up the reservoir, based on the well logs of different types of well logs distributed in the interwell space and the revealed dependence of the reservoir properties of the reservoir and logs of each type.

9. According to the obtained reservoir properties of the reservoir, by means of hydrodynamic modeling, for example, justify the placement of production wells.

The advantage of the present invention over the prototype is that it is more reliable to determine the reservoir properties of the reservoir by expanding the complex of geophysical research of wells and Fourier-coordinated analysis of changes in logs in the interwell space, while the input data are log diagrams that are not necessarily pairwise known in all considered wells . This makes it possible to increase the efficiency of monitoring and managing field development, increase the efficiency of drilling operations, reduce the risks of incorrect estimation of technological indicators when constructing geological and hydrodynamic models, and more reliably place production wells.

An example of a specific implementation of the method.

For one of the sections of the Malobalykskoye field, it is clearly shown that the proposed method significantly improves the quality of control over the development and placement of production wells planned for drilling.

The considered section of the Malobalykskoye field represents deposits of the Achimov strata, which correspond to deep-sea facies. One of the main conditions for the formation of sand-aleuritic sediments of the Achimov sequence is the excess of the rate of arrival of clastic material over the rate of sinking of the sedimentation basin. Sea level fluctuations are reflected in the section by alternating strata of sandstones and clays. The layers formed during the regression cycle during the subsequent transgression were overlapped by a pack of clays, and the whole process was repeated, spatially shifting westward. Taking into account the geological, geophysical and lithological information, Achimov deposits were formed in connection with the arrival of sand-silt sediments in the form of turbidite flows of various densities, landslides and planar washes at the foot of the Neocomian shelf terraces. These phenomena are genetically and spatially associated with the areas of discharge of sediments transported by the alluvial-delta systems of the basin.

The considered layer of the Achimov stratum is an integral part of the wedge-shaped and fundoform zones of clinocyclite, which was formed through avalanche sedimentation and clear labeling of cycles with clay episodes (interruptions) associated with the passivity of sources of sedimentary material.

The considered reservoir in the analyzed area of the Malobalykskoye field consists mainly of the facies of the gravitational flow, which is an intercalation of fine-grained siltstone sandstone and mudstone with a layered texture and with erosion and traces of agitation. Thus, the high ruggedness and high clayiness coefficient of the formation section indicate that the field of geological and geophysical characteristics is unsteady and for more effective prediction of filtration-capacitive properties, additional types of well logging are necessary.

In particular, it is necessary to prescribe additional to the standard GIS complex gamma-gamma-ray logging in its density modification (GGK-P) for a more accurate assessment of the distribution of filtration-capacitive characteristics / filtration-capacitive properties (FES) in the section of the reservoir. Moreover, only one type of logging is actually used from the standard complex for assessing the filtration-capacitive properties. At the Malobalykskoye field, the location of production wells and development control are carried out on the basis of a geological model constructed by combining seismic data, geophysical well surveys and core core studies. In particular, only one type of logging from the standard well logging complex — spontaneous polarization (PS) logging — is used to isolate reservoirs and evaluate reservoir properties. Logging PS compared with GGK-P logging has lower vertical resolution and weakly responds to the layered structure of the formation, which leads to a less accurate assessment of the distribution of reservoir properties in the section of the formation and, therefore, complicates control over the development. In addition, the correlation "GGK-P porosity - core porosity" is much better than the correlation "PS porosity - core porosity". However, subsurface logging allows you to identify sandstone distribution trends on a larger scale and can be used in geological modeling to take into account sandstone distribution trends within the reservoir, and GGK-P logging to take into account sandstone distribution trends within bodies. Thus, an additional study of the formation by GGK-P logging at the Malobalykskoye field and its use in determining porosity allows more reliable determination of the reservoir properties of the formation.

Until now, however, if it was necessary to use, for example, two types of logging, it was required to conduct both types of logging on each well under study, since there was no way to coordinate the distribution of two types of logging diagrams.

The proposed method, in contrast to the prototype, involves the coordinated distribution of two types of logs, obtained not necessarily on the same well. Only a part of the studied wells was covered by the two indicated types of well logging. The other part of the wells was covered either by PS logging or GGK-P logging.

Under such conditions, one of the goals of geological modeling is the implementation in the model of vertical variability, connectivity, and taking into account the distribution trends of sand bodies and FES through additional research of GIS.

As a result of using the proposed method due to additional GGK-P logs, the amount of additional input information for predicting the reservoir profile increased by 20%, which, in turn, leads to an increase in the reliability of development control. In this case, quantitative criteria for assessing the FES were used.

The application of the prototype method leads to large errors in the control of development. This is explained by the non-use of additional GGK-P logging in the prototype and the inability of the prototype method to explicitly take into account the distribution trends of the FES inside sand bodies. The application of the proposed method in the selected area significantly increased the reliability of the location of production wells, as evidenced by a comparison of model logs (obtained by the claimed method) in the undrilled area with the actual logs obtained after drilling a new production well in this undrilled area. Moreover, in the drilled production well selected for analysis, both the logging of the substation and the GGK-P logging were carried out.

The figure shows a comparison of the logs obtained in different ways, as well as the actual log diagram in the new production well: the left column is the actual log diagram, in the center is the prototype, on the right is the proposed method. It can be seen that the proposed method with higher reliability predicts the behavior of logs and, accordingly, the structure of the formation and the values of the reservoir properties in the undrilled area of the formation.

Thus, the proposed method allows more reliable prototype to determine the reservoir properties of the reservoir and the relative position of the parts that make up the reservoir in the interwell space of unexplored sections of the reservoir, it is more reliable to monitor the development and more reliably place production wells.

Information sources

1. Baykov V.A., Bakirov N.K., Yakovlev A.A. New approaches to the issues of geological and hydrodynamic modeling, Oil Industry, 2010, No. 9, P.56-58.

2. Guidelines for calculating oil and gas reserves by the volumetric method. Edited by N.I. Petersilier, V.I. Poroskun, G.G. Yatsenko. - Moscow-Tver: VNIGNI, Scientific and Practical Center “Tvergeofizika, 2003”.

Claims (1)

A method for monitoring reservoir development, including seismic surveys, geophysical well surveys, laboratory core studies, revealing the interdependence of reservoir and reservoir characteristics of the reservoir and well logs from a combination of laboratory research data, identifying the structure of seismic surveying and geophysical studies of wells formation, determination of reservoir properties and relative position the parts that make up the reservoir, based on common logs in the interwell space of unexplored sections of the reservoir and the revealed interdependence of the reservoir characteristics of the reservoir and logs, characterized in that at least one more type of logging is additionally carried out during the geophysical exploration of wells, moreover additional logging is carried out at any well, and the reservoir properties of the formation and the relative position of the parts of the formation are determined by Fourier-consistent analysis of changes in all obtained logs in the interwell space.

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