RU2214505C1 - Oil pool development method based on system detection of wells flooded with extraneous water, their repair and putting on production - Google Patents

Abstract

FIELD: oil producing industry; applicable in development of oil pools at various stages of development. SUBSTANCE: method includes oil withdrawal through producing wells, water injection through injection wells, detection of wells producing extraneous water, elimination of inflow of this water and putting on production of this wells. Method is distinguished by the fact that said wells are detected by system method. For this purpose, actual dynamics of oil recovery for period of operation is compared with calculated dynamics produced on adapted geological- technological model for wells whose geological-oil field conditions do not predetermine possibility of their flooding with water of operated formation. Wells flooded with extraneous water are determined by value of excess of calculated oil recovery over its actual recovery. Volume of this water is evaluated. In wells with more than two fold excess of calculated oil recovery over its actual recovery, oil field-geophysical researches are carried out for detection of sources of flooding. Inflows of extraneous water are eliminated by repairs of wells with inflows of extraneous water proved by performed researches. EFFECT: increased current oil recovery and increased fullness of its reserves recovery. 1 dwg, 1 tbl, 1 ex

Description

 The invention relates to the oil industry and can be used in the development of oil deposits that are at different stages of development.

 A known method of developing an oil reservoir, including water injection through injection wells, oil extraction through production wells, field geophysical monitoring of development and identification of wells producing extraneous water, their repair and commissioning ("Extraneous" water is the water entering well not from the developed production facility).

 Such a traditional work procedure or development method is described in the special literature on oilfield geology and on the exploitation and development of oil fields [1], [2].

 In [1], it is noted that in practice, cases of flooding production wells due to annular circulation between the perforation interval and the underlying aquifer are quite widespread. The annular circulation interval usually does not exceed 10-15 m. To isolate the annular circulation interval under such conditions, the radioactive isotope injection method is used. Compared with other known methods, the injection of radioactive isotopes is most effective.

 As a source of watering, there may be an aquifer lying close to above or below an exploited deposit.

 In the method [2], to determine the intervals of casing leakage, which can be a source of foreign water entering production wells, as well as to determine annular circulation, in which extraneous water through perforation holes enters the production well, flooding the produced products, it is recommended to use geophysical methods with indicating specific types of measurements.

 The closest analogue of the proposed method is the method [1].

 The disadvantage of this method is that according to the results of geophysical studies it is not possible to quantify the volume of extraneous water produced by the well. Due to this, it is impossible to estimate the scale of the process of producing this water by faulty wells, especially in the entire history of the development of the reservoir.

 For the same reason, in assessing the state of development of deposits, the rate of extraneous water production is not used at all as a characteristic of the current state of development, and this seems to be a certain omission, because the amount of produced foreign (extraneous) water during the development of the reservoir can be very significant, and will cause large additional material costs for its extraction and water injection for unnecessary compensation of extraneous water withdrawals.

 The technical result of the proposed method is to eliminate the noted drawbacks of the known method, namely increasing the current oil production and increasing the completeness of extracting its reserves due to a systematic approach to identifying foreign water producing wells, and providing the possibility of quantifying the volume of foreign water produced by the well.

 The technical result is achieved by the fact that in the method of developing an oil reservoir, including the selection of oil through production wells; water injection through injection wells; identification of wells producing extraneous water; the liquidation of the inflows of this water, the commissioning of these wells, and the increase in oil production due to this, according to the invention, systematically identify such wells, for which a comparison is made of the actual dynamics of oil production with the calculated obtained on the adapted geological and technological model, for this, wells are used, the geological and fishing conditions of which do not determine the possibility of intensive watering of the developed production facility with water, in magnitude (ΔQн), exceeding the estimated production n Oil (Qn. p.) over its actual production (Qn.p.) identify wells that are flooded with extraneous water, estimate the volumes of this water in wells with more than double Qn.p. Above On.F., field geophysical studies are carried out to identify sources of watering, the flow of this water is eliminated by repairing wells with foreign water inflows confirmed by these studies, and they are put into operation with large oil production rates, increasing the total oil production from the reservoir.

 The systematic approach is that all wells that have been in operation are analyzed, and the foundation identified in this way is a full-fledged basis for targeted planning of geophysical surveys to control development, which as a result allows to reduce material costs for inspection of wells that are not priority.

 As you can see, the justification of wells for conducting GIS control is based on a comprehensive geological and field accounting of capacitive-filtration properties and technological indicators of well operation.

 The implementation of the proposed method determines the need to create a geological and technological model. The basis of such a detailed model, as you know, is laid the real capacitive-filtration properties of reservoirs of developed productive horizons. Therefore, the adapted geological and technological model [3] fairly objectively displays the filtration processes occurring in the reservoir.

 The method of developing oil deposits is as follows.

 First, wells are selected where the fact of irrigation with extraneous water, for example, inflow of water from an upstream or downstream horizon through an annular space through perforations or through leaks in the production string, is established by GIS control methods.

 For each well of this group in the entire history of operation, the dynamics of the calculated and actual production of liquid and oil is built and compared. As a result, an image is created of the dynamics of the extracted watered products and the nature of their discrepancy with the estimated oil production.

 Then, wells are selected in which GIS monitoring studies, i.e., geophysical studies to control the development, have not been carried out, but which have actual oil production dynamics and discrepancies between actual and estimated oil production dynamics, similar to those of the first wells groups.

 Such wells are first recommended for conducting field geophysical studies in them to identify sources of watering, and in the event of confirmation of the receipt of extraneous water in them, they are proposed for the isolation of water inflows.

 For the analysis, mainly wells are used, the geological and production conditions of which do not determine the possibility of intensive water flooding of the developed exploitable object.

 The near-borehole space of such wells is composed in most cases by a uniformly inhomogeneous pack of reservoirs, among which there are no interlayers with abnormally high permeability. Wells are removed from the external, internal oil circuits and from injection wells.

 Wells should not be used whose geological conditions may cause intensive flooding with their own water, i.e. water operated exploitation facility.

 These are wells with bottom water in the immediate vicinity of the perforation interval, wells located close to the external or internal oil circuits or located close to injection wells, as well as wells in the cross section of which there are separate highly permeable interbeds through which leading flooding can occur.

An example of a specific implementation of the method
The method was tested in one of the fields of Western Siberia.

 Description of the geological structure of the development object.

The AB ₁ ³ and AB ₂ ¹ formations are represented by a series of sand-clay deposits. According to morphological and filtration properties, two types of collectors are distinguished: reservoirs of monolithic structure and thin-layered alternation. The first have high permeability (200-500mD). The permeability of thin-layer reservoirs, as a rule, varies in the range of 30-50-70 mD. The layers AB ₁ ³ and AB ₂ ^{1 are} divided. The total thickness is 6 and 40 m, respectively. The reservoirs are characterized by initially low oil saturation and mobile pore water.

 The facility was put into commercial development in 1986. 580 wells were in operation. As of January 1, 2000, there were 475 wells in the production fund and 178 wells in the injection fund. All producing wells produced waterlogged products. Annual oil production of about 900 tons The water content is 81%. Liquid production 4.7 million tons The average well production rate for oil is 12 t / s, and fluids are ~ 63 t / s. The development system is block. Each block is bounded on four sides by rows of injection wells. Characteristic of the process of reserves development is low oil recovery (12.8%) with a high degree of water cut (81.0%). The accumulated oil and water factor is estimated at 1.7.

 In accordance with the regulated procedure, a detailed three-dimensional three-phase geological and technological model was first created.

 Geological modeling was carried out using the YRAP RMS software package, and technological modeling was based on the MORE package. The entire 16-year history of the development of the facility was reproduced. All wells with a long history of production were adapted. The discrepancy between accumulated oil production, calculated and actual, did not exceed 2%.

 In accordance with the regulated procedure, wells were first selected in which, according to the GIS-control, inflows of extraneous water were established. There were 80 such wells (see table).

 The drawing shows a typical picture of the dynamics of the actual and estimated oil production for wells of this group.

 Then wells were selected with the dynamics of the actual and estimated production of liquid and oil, similar to that shown in the drawing, but for which geophysical studies to identify sources of flooding were not carried out. There were 123 such wells.

 Next, we conducted an analysis of the geological and field conditions of 123 wells with irrigation water with the aim of identifying geological and field conditions in the near-borehole space that could contribute to intensive water flooding of the wells with our own water. There were 29 such wells. These are mainly waterlogged wells located in the oil and water zone of the reservoir.

 There were 94 wells that extracted extraneous water and were characterized by geological and fishing conditions that did not predetermine the possibility of flooding with their own water.

 In these 94 wells, according to the recommended method, field-geophysical studies were conducted to identify sources of flooding. Direct studies confirmed the water cut of foreign wells by extraneous water (see table).

 Then all these wells were transferred to overhaul to eliminate sources of flooding. Over the course of 2 years, repair work was carried out in 73 wells, including 40 wells in the first year, and 33 wells in the second year.

 Calculation of additional oil production due to an increase in the productivity of wells irrigated by extraneous water after carrying out repair work in them is given below.

 Calculation of additional oil production provided by systematic identification and subsequent repair of wells irrigated with extraneous water (73 wells indicated in column 4 of the table were included in the calculation).

 Wells are divided into two groups, in accordance with the time of repair work in them.

 In the first year, 43 wells were repaired (this is the first group of wells); in the second year - 30 wells (second group).

a) Average performance of the well of the first group, before the repair work: q _w - 54 t / s, f _in - 96%, q _n - 2.2 t / s,
where q _W is the fluid flow rate, f _in is the water cut, q _n is the oil flow rate.

b) and c) Performance indicators of the averaged well of the first group, respectively, in the year of the isolation work, and for the next year:
b)
q _w - 37 t / s
f _in - 63%
q _n - 13.7 t / s
t - 133 days

K _e - 0.75
Δq _n - 11.5 t / s
in)
q _w - 39 t / s
f _in - 71%
q _n - 11.3 t / s
t - 273 days

Δq _n -9.1 t / s
where t is the operating time,
To _e - coefficient of operation,
Δq _n - the increase in average daily flow rate.

g) Performance indicators of the averaged well of the second group in the year of the isolation work:
before - after
insulation work - insulation work
q _w - 58.7 t / s - q _w - 49.0 t / s
f _in - 95.4% - f _in - 67.5%
q _n - 2.7 t / s - q _n - 15.9 t / s - Δq _n - 13.2 t / s - t - 133 s
ΔQн (first group of wells) = (43 • 11.5 • 133) + (43 • 9.1 • 273) = 172593.4 t.

 ΔQн (second group of wells) = 30 • 13.2 • 133 = 52668 t.

 In both groups, in two years, ΔQH amounted to 225.2 thousand tons.

 The results of experimental work on the practical use of the proposed development method, based on the systematic identification of wells flooded with extraneous water, their repair and commissioning, indicate the effectiveness of the method.

Sources of information
1. The prototype - B. M. Orlinsky. Control over the development of oil deposits by geophysical methods. Moscow. Nedra, 1977, p. 45.

 2. Methodological guidelines for hydrodynamic, field-geophysical and physico-chemical methods for monitoring the development of oil fields (p. 329, table. 6.2, p. 9, RD-39-100-91).

 3. The regulation on the creation of permanent geological and technological models of oil and gas and oil fields (RD 153-39.0-047-00). Ministry of Fuel and Energy of the Russian Federation. M., 2000.

Claims (1)

 A method of developing an oil reservoir, including taking oil through production wells, injecting water through injection wells, identifying wells producing extraneous water, eliminating inflows of this water, and commissioning these wells, characterized in that these wells are systematically detected, for which a comparison is made actual dynamics of oil production during the operation period with a calculated one obtained on an adapted geological and technological model for wells whose geological and production conditions are not predetermined they can be intensively irrigated with water at the facility in operation, by the excess of the estimated oil production over its actual production, wells that are irrigated with extraneous water are identified, the volumes of this water are estimated, and wells with more than double the estimated oil production over its actual production carry out field geophysical studies to identify sources of flooding and the elimination of foreign water inflows is carried out by repairing wells with inflows confirmed by these studies by outside water.

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