Vol 24, No 2 (2024)
- Year: 2024
- Articles: 7
- URL: https://ered.pstu.ru/index.php/geo/issue/view/414
ARTICLES
Modeling of the Dynamics of Fractal Characteristics of Micro-Fractured Fluid-Saturated Reservoirs while their Deformation
Abstract
One of the primary factors that affects the effectiveness of the processing of oil and gas deposits is the natural or artificially altered movement of liquid in the formation (hydrodynamic processes). Besides, the natural flow of liquids in the productive layers can be complicated by the factors related to the methods of increasing oil recovery in the layers, such as hydraulic fracturing of layers. Typically, these actions are performed in order to enhance the production of oil and gas, as well as improve the efficiency of oil extraction. Nevertheless, due to these activities, the productive reservoirs, which are porous and permeable matters, change into different stress conditions (destructive states). These conditions are identified by the amount of fissures within a single volume (unit) of rock and the specific pattern of fluid flow within reservoir. This article is reflecting investigations on how reservoirs deform and develop a system of fractures with a fractal pattern. Additionally, a model, which explains how these cracks system are generated, considering the changes in the fractal dimension of the media. According to the conducted researches, further phases of the process of formation of cracks have been pointed out. First, several initial cracks occur which have a chaotic disordered arrangement. Simultaneously, the fractal dimension of the system increases to a value of 1.6. During the subsequent phase, as the fractal dimension gradually rises from 1.6 to 1.73, the initial cracks start merging and creating a ruptured area. Next, the fractal dimension remains relatively stable, and once it reaches 1.75, there is a sudden break or disruption in the integrity of the medium. The reasons for possible inconsistency is in simulated crack formation, which can be attributed to the presence of multiple levels of heterogeneity and defects within real geological materials. These variations occur because of fluctuating micro- and macro stresses that are distributed among these heterogeneities.
Perm Journal of Petroleum and Mining Engineering. 2024;24(2):52-57
Development of a Complex Geochemical Criterion that Determines the Distribution of the Total Oil and Gas Content of the Solikamsk Depression section
Abstract
The results of a probabilistic-statistical assessment of the geochemical characteristics of the section of the main oil and gas source strata of the Solikamsk depression and their relationship with the total oil and gas content of the section are presented. For comprehensive accounting and identification of the optimal combination of geochemical parameters that determine the oil and gas content distribution, a complex probabilistic criterion has been developed for each oil and gas complex - Rcomp. Statistical analysis confirmed that the Upper Devonian-Tournaisian deposits in most of the Solikamsk Depression territory were in the main phase of oil formation, and there the maximum mobile bitumen formation occurred, including hydrocarbons, which took an active part in the total oil and gas content formation of the Solikamsk Depression. A fundamentally different nature of changes in the values of the developed complex geochemical criterion has been established in depth for wells located within the oil and gas bearing contours and beyond them. The most informative criterion indicating the relationship between DOM and the total oil and gas content of a section is the bitumen coefficient β.
Perm Journal of Petroleum and Mining Engineering. 2024;24(2):58-64
Energy Potential Analysis of Facially Heterogeneous Carbonate Reservoirs in the Process of Hydrocarbon Reserves Development
Abstract
Analysis of the energy state of a deposit is an integral part of field development monitoring. Now, a significant volume of production in the Perm Krai comes from complex carbonate reservoirs, which are characterized by heterogeneity both vertically and laterally, different filtration and reservoir characteristics, alternation of different types of void space, and a large coefficient of compartmentalization. Under such conditions, the need for constant monitoring of the reservoir energy state, in particular the dynamics of reservoir pressure, increases. In this work, using the example of the T-Fm-Fr carbonate deposit of one oil field located in the Perm Krai in the northern part of the Solikamsk depression, an analysis of changes in reservoir pressure in various lithological-facial zones since the beginning of well commissioning was carried out. The four zones identified as a result of facies analysis are characteristic of fields confined to the reef reservoirs of the Solikamsk Depression and are characterized by different geological structures. It is generally accepted that the filtration and reservoir properties of a reservoir, field reserves and well flow rates can directly depend on lithological-facial zoning. Thus, as a result of the study, it was established that the facies of the upper part of the rear plume of the reef was characterized by the maximum amount of accumulated fluid production and the best filtration and reservoir properties. However, based on the magnitude of changes in reservoir pressure in wells, obtained using artificial intelligence methods in the Data Stream Analytics program, and when calculating statistical criteria, it was established that the features of the facies environment did not significantly affect the magnitude of changes in reservoir pressure from the beginning of putting wells into operation. The calculated criteria confirmed the different amounts of accumulated oil and liquid production by facies and were not statistically significant for the magnitude of changes in reservoir pressure. The results of the study indicated the need to take into account all facial zones as a single development object when choosing the optimal system for maintaining reservoir pressure and selecting well stimulation.
Perm Journal of Petroleum and Mining Engineering. 2024;24(2):65-71
Application of Fiber Optic Thermometry Monitoring in the Control the Formation of Cement Stone in the Well Annulus
Abstract
A promising method for monitoring the process of waiting for cement hardening in wells is the use of fiber optic well thermometry or distributed temperature sensing (DTS). The DTS method creates the opportunity to move from post-facto measurements to real-time monitoring with the identification of complicated areas and timely adoption of the necessary design decisions. As a result of the research, the technology for thermometric monitoring of the process of cement stone formation was developed. The purpose of the work was to determine the applicability of practical skills developed over more than 10 years in the field of production geophysical research using the DTS method to solve the applied problem of well construction. It was established that the data obtained from DTS, in addition to solving applied problems (determining the reaction temperature, data on the result of cementing, etc.), made it possible to solve the problems of monitoring the processes occurring in the annulus during the formation of cement stone and create a platform for the further development of technologies for rapid response to identified complicated areas. The results of the work performed can be widely used in monitoring the well construction process, and are also of interest from the point of view of further development, both from a technological point of view and methodologically.
Perm Journal of Petroleum and Mining Engineering. 2024;24(2):72-77
Investigating the Influence of Reservoir Pressure on Porous Media Permeability: A Case Study of Fields in the Perm Region
Abstract
Field studies of permeability changes were analyzed using the example of oil fields in the Perm Krai; laboratory studies of the effect of effective pressure on core permeability were carried out. An analysis of existing methods for assessing changes in rock permeability depending on effective pressure showed that in most cases, researchers use empirical dependencies obtained by approximating experimental data. Analysis of the results of laboratory studies showed that, regardless of the type of rock, the greatest decrease in permeability during elastic deformations was observed in highly permeable samples of limestone and sandstone and was amounted to up to 20%. It was established that the dependences of the permeability of limestone and sandstone samples under purely elastic deformations ware described with high accuracy by exponential equations. The calculated coefficients of the equations describing the change in permeability were compared based on the results of field and laboratory studies. The mechanism of deterioration in the permeability of productive formations with a decrease in reservoir pressure was revealed, on the basis of which a model is proposed that takes into account elastic and plastic deformations of porous reservoirs. It was established that highly permeable formations were most susceptible to plastic deformation with the formation of deformation bands. In layers with greater thickness, the probability of a decrease in permeability with a drop in reservoir pressure increased, which was associated with the formation of transverse deformation bands.
Perm Journal of Petroleum and Mining Engineering. 2024;24(2):78-85
The Influence of Clay Minerals Swelling on Reserve Production
Abstract
During the oil and gas reservoirs development, various processes occur, ranging from varying the physicochemical properties of formation fluids to changing the reservoir properties of productive formations, which leads to their destruction. All these processes can influence the final oil recovery in different ways. Research into the influence of clays on the permeability of sandstones has been conducted for more than 50 years, but the presence of clay minerals in reservoir rocks still poses a problem for oil production. When oil is displaced from productive formations, the injected water interacts with the clay minerals of the rock, which leads to significant changes in the dynamics of oil production in the fields. This parameter can especially change when maintaining reservoir pressure by injecting fresh water, since the composition of the injected water significantly affects the permeability of reservoirs. In addition to the type and spatial distribution of clay minerals, another important component that influences the degree of permeability change is fluid composition. Basically, the reduction in permeability occurs when the injected water is less mineralized than the formation water. To establish the dependence of swelling on clay minerals, the work analyzed the results of 1007 laboratory samples that were used to study the mineral composition of clay fractions. To identify the dependence of swelling on various clay minerals, a significant number of graphs were constructed and a relationship was established between swelling and mixed-layer formations of the hydromica-montmorillonite series, which made it possible to establish the swelling values for other fields. To determine the effect of swelling on the change in porosity, a coefficient for reducing porosity due to swelling was introduced. The calculation of oil reserves for the YuV1 layer of 13 fields showed that when taking into account the clay minerals swelling, the value of reserves decreased by an average of 8.6%. It was shown that the injection of fresh water led to the destruction of reservoir rocks of fields with high swelling and low porosity, which was confirmed by the low production of reserves for other fields characterized by opposite values of swelling and porosity. Freshwater injection did not affect production from initial recoverable reserves.
Perm Journal of Petroleum and Mining Engineering. 2024;24(2):86-92
Forecasting Hydraulic Fracturing Results Using Information Amount Theory
Abstract
Hydraulic fracturing allows you to increase production from wells and reduce the time it takes to extract oil from reservoirs. The article examines the carbonate formations of the Perm region. Hydraulic fracturing is being actively carried out on these formations. To properly plan hydraulic fracturing, it is necessary to determine the main factors that affect oil production after hydraulic fracturing. The study used information amount theory to identify the main factors that influence the results of hydraulic fracturing. For the area considered, the main factors were: pre-frac water cut, fracture width, fracture length, pre-frac oil production rate. Having data on these parameters, it is possible to predict hydraulic fracturing with high reliability. The regression model is built by the method of multiple linear regression. To determine the group features, a statistical analysis of the key parameters was performed to draw box plots of the mean, maximum, median, quartile and minimum values for each parameters. First, we analyzed the results for all parameters. The graph show that the productivity increases with increasing the oil production rate after fracking and the fracture width, and the group B had the largest amount; therefore its production is expected to be large. The others parameters were similar in the groups A and B. The absolute deviation of the second model calculated values of the oil production rate after hydraulic fracturing from its values in the field regress from 1,287 to 0,662 compared in the first model calculated values. The relative deviation from 4.1 % in first model to 2.4 % in the second model calculated values. The results obtained will allow us to quickly predict hydraulic fracturing in new wells.
Perm Journal of Petroleum and Mining Engineering. 2024;24(2):93-100