RU2611131C1 - Method for detection of watering wells and water inflow intervals in gas wells - Google Patents

Abstract

FIELD: oil-and-gas industry.

SUBSTANCE: invention relates to gas industry and can be used for identification of watering wells and water inflow intervals. The method comprises performing without well shutoff of background and monitoring humidity metering studies of complete operating well stock, on the basis of which the group of possible watering wells is identified. By changing the depression the increment of vapour phase values, velocity and flow rate of gas flow in either direction, or absence of increments are detected. Based on these results the watering well is identified. It is used for execution of nuclear studies for identification of watering interval or multiple intervals. In these intervals the geological and technical measures for water shutoff in order to increase the gas recoverability are performed.

EFFECT: invention consists in improvement of reliability of determination of watering wells and water inflow intervals.

1 tbl, 1 dwg

Description

The invention relates to the gas industry and can be used, through a search for a watering well and a watering interval in it, for the application of geological and technical measures for waterproofing works.

The premature flooding of gas deposits at the initial stages of operation and in the mode of declining production negatively affects the efficiency of the operating activities of production companies in production. A serious problem is the organization of the identification of water wells. A watering well is a source of watering not only itself, but also neighboring wells. Signs of additional water appear in all wells of the bush, so the task of identifying the source of watering the bush is very difficult.

Existing technologies for special research of wells through separation plants in combination with geophysical exploration are costly, extended over time; track part of the existing fund, but the most important are unreliable (for example, RU 2081311 C1, IPC ⁶ ЕВВ 47/00, publ. 1997). A direct confirmation of this is the history of insulation work (over 20 years) with unsuccessful results. Therefore, to date, the production operator practices the implementation of waterproofing works in the stopped (due to flooding) wells. The end result of such work is loss of production and a significant increase in costs.

A known method of detecting waterlogged wells in the development of oil deposits [RU 2214505 C1, IPC ⁷ Е21В 43/16, ЕВВ 43/32, publ. 2003], including the selection of oil through production wells, injection of water through injection wells, identification of wells producing extraneous water, elimination of inflows of this water, and commissioning of the well. At the same time, a systematic approach to identifying waterlogged wells is carried out, which consists in comparing the actual dynamics of oil production during the operation period with the calculated one obtained on an adapted geological and technical model for wells whose geological and production conditions do not predetermine the possibility of intensive watering of the operated facility; by the magnitude of the excess of the estimated oil production over its actual production, wells that are flooded with extraneous (injected) water are identified; estimate the volume of this water; in wells with a more than twofold excess of the estimated oil production over its actual conduct geophysical surveys - control (GIS control) to identify the interval of flooding.

Consideration of the history of oil and water production plays a very positive role and is often effective, since reservoir pressures for water and oil are quite close. But the complete transfer of this method to gas reservoirs (wells) cannot be effective due to the large difference in reservoir pressures of the intake and exhaust gas intervals. The next reason for the impossibility of applying the proposed method in gas wells is the different rates of flooding (blocking water) in gas and oil wells. In gas wells, only the appearance of additional water, sometimes, leads to a fairly rapid flooding: within 1 week-1 month. And there is not enough time for preventive measures. In an oil well, from the moment of registration to the moment of shutdown, the process is quite lengthy and reaches 1 year or more.

A known method of detecting waterlogged wells in the development of oil deposits, including the injection of a working agent through injection wells, oil extraction through production wells [RU 2231632 C1, IPC ⁷ Е21В 43/16, Е21В 47/10, publ. 2004]. Gamma-ray curves are recorded during the operation of the wells (monitoring of measurements). For the studied wells, the subsequent and previous gamma-ray logging curves are combined. A difference curve is constructed between the gamma units of the subsequent and previous curves. The maximum difference between the values of gamma units is taken as 100%, the dynamics and percentage of changes in gamma units in the zones of productive layers are determined. It is assumed that the movement of formation water is weak with a change in gamma units up to 25%, from 25% to 75% - average; more than 75% is intense, that is, by the presence of watering dynamics, they are judging the progress of formation water to the well. In irrigated interlayers, water isolation measures are carried out. By alignment of the injectivity profile in the wells, gamma-ray curves are recorded before and after waterproofing works. By the abrupt change in gamma-ray indices, the passage of the water-insulating agent into the flooded layers is judged. The proposed method is a long, laborious process. The injection of water into gas wells and the determination of injectivity when injecting a water-insulating composition are dangerous in view of the large pressure drops between the gas extraction and water supply intervals, which often lead to the absorption of large volumes of process fluids, the extraction of which takes from 1-2 months or more, when the difference in reservoir pressure is several tens of units, with a value of reservoir pressure, gas extraction interval, 18-20 kgf / cm ² . Nuclear geophysics methods used to detect waterlogged intervals in oil wells record the occurrence of labeled water in the strata, rather than the source of flooding.

In gas wells show mixed results in environments containing gas and density differences. In addition, it is not watering sources that are identified, but flow intervals. As a result of waterproofing works, the overflows are liquidated, the effectiveness of which is short-term. When injecting labeled fluid, it is unambiguous to identify waterlogged intervals (as a result of formation water movement) by nuclear geophysics, since it spreads throughout the entire productive stratum, including upstream and downstream formations.

A known method of monitoring the process of watering a gas well, including conducting standard gas-dynamic studies of gas wells at stationary filtration modes and determining the coefficients of filtration resistance over time, build graphs of their changes over time, then compare the values of the coefficients of filtration resistance with the previous ones and conclude that formation water in the bottom-hole zone of the reservoir by an abrupt increase in the values of the filtration resistance coefficients [RU 2202692 C2, IPC ⁷ Е21В 47/00, ЕВВ 43/32, publ. 2002].

The disadvantage of this method can be attributed to low reliability associated with large intervals for conducting gas-dynamic studies.

The problem to which the claimed technical solution is directed is to develop a method for identifying an object of irrigation (source) with a high degree of reliability that provides quick coverage of the existing fund, while reducing material and technical costs to ensure an increase in the gas recoverability coefficient.

In the implementation of the proposed technical solution, the problem is solved by achieving a technical result, which consists in increasing the reliability of the determination of watering wells and water supply intervals in it.

The specified technical result is achieved by the fact that the method for detecting water wells and water supply intervals therein includes conducting, without stopping the wells, background and monitoring hydrometric studies of the entire existing stock, on the basis of which a group of wells, potential water cutters is identified, then an increment of values is recorded by changing the depression per well vapor phase, velocity and flow rate of gas flow in one direction or another or the absence of increments, on the basis of which the well is detected, vodnitelnitsu in which nuclear research carried out to detect flooding interval or intervals for several of them wellwork for water shutoff in order to increase the coefficient of gas extractability.

The drawing shows the current diagnosis of the reservoir model of the watercutter well.

A well-watered well is understood to mean a source of watering not only of itself, but also of neighboring wells. Signs of additional water appear in all wells of the bush, so the task of identifying the source of watering the bush is very difficult.

A method for identifying an object of flooding (source) consists of several stages.

First step.

The goal is to identify a group of wells, potential water cutters. A tool for identifying water wells is background moisture measurement of the entire existing fund. A sign of the selection of wells in this group is:

the vapor phase of the gas stream exceeds the average value for the year by at least 2 times (example: the average increment of the vapor phase for the year 0.2 g / m ^3. Next, wells with an increment of 0.4 g / m ³ or more are selected, i.e. the value of the vapor phase that does not correspond to the current thermobaric conditions or differs sharply from the calculated values);

registered significant decreases in gas flow rate and flow rates associated with an actual decrease in the extraction zone, that is, with the presence of additional water in the extraction zone, which blocks the gas supply to the perforations;

the presence in the sample of a drop liquid of a mixed type with the content of reservoir and condensation.

Algorithmic criterion for the presence or absence of additional water (the calculated value of the vapor phase corresponding to thermobaric conditions is calculated by the Bukachek formula (A.I. Gritsenko, Z.S. Aliev, O.M. Ermilov, V.V. Remizov, G.A. Zotov, A Guide to Well Research, Moscow, Nauka, 1995. - P. 64-71):

W _0.6 = A / P + B,

Where:

W _0.6 is the calculated value of the vapor phase (g / m ³ ) at a gas density of 0.6 kg / m ³ ,

A is a coefficient equal to the content of an ideal gas;

P is the pressure, MPa;

B - correction for the imperfection of natural gas.

A change in the vapor phase that does not correspond to thermobaric conditions makes it possible to identify or the presence of additional water in the selection zone. The presence of additional water is estimated by the difference between the calculated and measured vapor phases.

Second phase.

The goal is to identify water wells from the selected group of the first stage based on changes in the vapor phase, speed and production rate, when the “load” changes (planned changes in depression - the pressure difference between reservoir (RPL) and bottomhole (Rzab) pressure, which ensures gas inflow to perforations (in the column): ΔР = Рпл-ΔРзаб) to the well, the result of which is the appearance of water with pressure. At this stage, only wells that are the source of flooding are investigated. If necessary, the monitoring of measurements in separate wells at time intervals not exceeding 1 month. Having 1-3 monitoring observations, get scalar and vector values of the changed values.

At the first and second stages, the proposed observation system covers the entire existing fund and responds to all changes in quarterly or monthly changes in depression to maintain the planned production rate occurring in the wells. Recorded no later than 20-30 minutes (from the moment of the changes) by the appearance of the corresponding gas packs at the mouth.

The observation system includes the following indicators:

vapor phase, g / m ³ ;

drop phase of water, kg / m ³ ;

salinity, type of water, g / l,%;

gas flow rate, m / s;

mass of gas flow, m ³ .

These parameters are evaluative in nature and cannot be called measuring. Changing the depression to the well, the increment of the values of the vapor phase, velocity and flow rate of the gas stream in one direction or another or the absence of increments, on the basis of which the well-waterer is detected, is recorded. The proposed observation system is carried out without stopping the wells, economical, environmentally friendly, provides information in a short time. At the moment, it is the most reliable of all types of field research. The registration process takes place under the same conditions, with the same set of equipment.

The advantage of the proposed system is the rapid coverage of the existing fund, low cost and higher reliability.

The third stage.

Types of watering in production gas wells:

interlayer flooding (breakthroughs of produced water or drilling fluid filtrates, when drilling onto underlying formations, into the AIP zones along the most permeable interlayers of a productive formation);

flooding in a monolithic formation (formation water breakthroughs in the formation);

plantar irrigation (pulling the water cone to the perforation interval due to the rise of GWC);

behind-the-casing water flows (foreign water entering the annular space as a result of poor separation of layers or a violation of the tightness of the cement ring);

leakage of the production string (water inflow into the well through violations of the production string).

interwell flows.

For example, in gas wells of the Yamal-Nenetsky fields, the flooding of the production of production facilities occurs as a result of a combination of several types of flooding. Common to all wells with watered production are water breakthroughs at highly permeable intervals of the formation located in various parts of the productive section and outside it. Therefore, reliable identification of intervals of water inflows of various types lies at the basis of the effectiveness of water-proofing measures, is decisive in nature of the cost or cost of mining products. To date, the only information tool that can reliably identify active interlayers saturated with low-mineralized water in a thin-layered section is wide-range spectral neutron gamma-ray logging (CISK-Sh).

Nuclear studies are carried out in the identified watering well with the CISK-Sh device to isolate the watering interval (or several intervals) in order to conduct geological and technical measures (geological and technical measures) for waterproofing works (VIR) in order to increase the gas recoverability coefficient. The operation of the CISK-Sh device is based on irradiation of rocks with a neutron flux from an ampoule source and registration of the thermal neutron flux density at two or more distances from the radiation source. SNGK-Sh includes, in addition to spectrometry, integrated methods of NGK, NNK, GGK-P. All information is extracted from the CISK-Sh spectrum. Simultaneous registration of the functions of hydrogen content, bulk density, lifetime, ratio of the parameters of scattering and absorption of thermal neutrons in one descent eliminates the ambiguity of interpretation. The resulting multi-method data does not require hardware, spatial and time reference. SNGK-III allows to obtain data similar to the two-probe integral NNK-T, NGK and GGK-P, and also allows to evaluate the neutron and gamma ray parameters of the studied media and their ratio. The information is very important for solving the problems of determining the current saturation of reservoirs, lithology of a thin-layered section, strength and filtration-capacitive properties of rocks of water intake intervals and fractured zones in the conditions of well flooding with weakly mineralized water. So, according to CISK-Sh, they create the current diagnostics of the production facility (see drawing). Research is carried out through the tubing and lubricator in the "dynamics" and "statics" modes. The CISK-Sh device is additionally equipped with a highly sensitive thermometer. The device is a 3-probe device. Three zones are examined in the radial direction: the first zone is 30 cm, the second zone is 50 cm, and the third zone is 80 cm. In conditions of difficult watering, a reliable current model of the production object is necessary to determine the interval and method of conducting waterproofing works.

To identify waterlogging intervals for CISK-Sh, temporary methodological recommendations for conducting and interpreting data for CISK-Sh are used (OAO NPP VNIIGIS, Oktyabrsky, 2002). The current diagnosis of the reservoir model in the water well (water supply intervals and their activity) is presented in the drawing.

When implementing the method, in particular, the following instruments and assessment tools were used.

The PIR-RG-601 device is an ultrasonic gas flow meter designed to measure the volumetric (mass) flow rate of liquids and gases flowing through a pipeline. One of the areas of application is the industrial enterprises of the fuel and energy complex. It is made according to specifications 4213-001-62730714-09 "PIR Technologies". It is entered in the State register of measuring instruments - registration No. 45257-10. The certificate of type approval of measuring instruments No. 40883 was issued by the Federal Agency for Technical Regulation and Metrology on 01/01/2010. The certificate of conformity No. РОСС RU.ГБ05.B03092 dated 05/12/2010 was issued by the National Center for Scientific and Technical Research. User manual - PIR.4011152.066 RP.

Thermohygrometer IVA-6 B - approved with technical and metrological characteristics given in the instruction manual (KING 7.772.001RE): GOST 12997-84; GOST 8.547-86 GSI; GOST 8.558-93 GSI; TU 4311-011-77511225-2005.

The selection of the dropping liquid from the gas stream with the UGMK-4 device is carried out in order to determine the chemical composition and type of water. The chemical composition of water is determined, in the field, by a fluid analyzer by the KSL conductometric laboratory multitest. KSL multitest is designed to measure the electrical conductivity of liquids (UEP), is manufactured according to the technical specifications of TU 4215-102-45444533-05 and meets the requirements of GOST 22171-90, is entered in the State Register of Measuring Instruments under No. 36742-08, certificate RI.S. 31.005.A№30269. Providing the measurement results - in terms of electrical conductivity (SEC) and total salt content in terms of sodium chloride NaCl. Mineralization is determined by NaCl (%). The content of NaCl determines the type of water:

condensation type (K) - NaCl≤1.0 g / l;

reservoir type (P) - NaCl≤18.0 g / l;

technogenic type (T) - NaCl> 18.0 g / l.

The composition of other elements, in the conditions of the Far North, can be neglected due to their meager content.

All measurements are carried out using a mobile laboratory, without stopping the wells and the release of gas into the atmosphere. Sampling is carried out on the surface through a socket for installing a manometer (VI 15) in the wellhead piping system. Measurements are taken at a long-term stable mode of operation of the well.

Evaluation of the quality of the gas stream (the moisture content of the gas flow of the production well for the presence of water in different phase states: vapor phase and droplet phase) is carried out through samplers using indicator methods.

Assessment Tools:

IVA-6B thermohygrometer; vapor phase; unit of measure - g / m ³ ;

"drop eliminator"UGMK-4; drop phase, the unit of measurement of the drop phase is kg / m ³ ; the goal is to determine the salinity and type of droplet water carried by the gas stream at the wellhead.

The purpose of the IVA-6B thermohygrometer measurements is as follows: to evaluate the content of the current value, the vapor phase, which carries information about the presence of water vapor (in this stable physical condition), in the sampling zone and at the mouth, in the sampled gas, while obtaining the value close to reliable.

The vapor phase carries information about the presence of water in reservoir thermobaric conditions.

The vapor phase is a stable form of the physical state of water. Gas is dried from the vapor phase on the surface using chemistry, pressures and temperatures (at the treatment facilities of the gas treatment plant), as the use of separation plants to separate the vapor phase is not effective. This indicates its steady state to various kinds of mechanical stresses.

All unstable states of water, as a result of the pressure difference (ΔР = Rpl-Rzab), are removed from the well by a gas stream in the form of a drop, which is taken on the surface of UGMK-4 to determine the salinity and type of water, which are determined at the assessment level. Having the result, the production operator himself, selectively, selects water in the same way and determines the chemical composition in his laboratory.

The dynamic characteristics (speed and flow rate) of a gas stream are evaluated by an ultrasonic gas flow meter (PIR RG-601), designed to measure the volumetric (mass) flow rate of liquids and gases flowing through the pipeline.

When determining the moisture content in the production of gas wells, you can use the method of rapid determination of moisture content [RU 2255218 C1].

The table shows the estimated data during the application of monitoring hydrometric studies of gas flow in production wells in order to search for a water well.

Qg - (PIR) - estimated measurements of gas production by the PIR-RG-601 device during the production of moisture measurements (column 3; 5), tm ³ / day;

Wg - estimated vapor phase measured by IVA-6B thermohygrometer, g / m ³ .

Wells that work intensively with additional water are wells in which the difference between the calculated and measured values of the vapor phase reaches 50% or more. In the example shown in the table, this value of the vapor phase (1.0 g / m ³ ) marks well No. 1a (measured from 08/06/2012), relative to neighboring wells and background measurements. Long-term operation of the well with such a vapor phase value leads to the destruction of the rock skeleton, the creation of sand plugs in the wellbore, flooding of the gas extraction interval, and the spreading of the water front into neighboring wells to zones with abnormally low reservoir pressures (ANP). Analyzing the data of the table, the following is established.

Well No. 2 "a" revealed aquifers; It is an observation of the movement of GVK in the bush.

Signs of watering appeared in the well of bush "a" - the value of the vapor phase in well 1 is 1.0 g / m ³ with the background value of the vapor in the reservoir 0.45 g / m ³ . With a decrease in depression, the value of the vapor phase in the wells of well "a" immediately decreased to 0.4-0.5 g / m ³ . Observation well 2a sharply reduced the flow rate, which clearly indicates the source of watering the bush - well 2a. The remaining wells of the bush slightly increased the flow rate, in view of the limitation of the source of watering. Conclusion: the well-flooder is well 2a. Taking into account the current diagnostics of the reservoir model of a watering well (see drawing), it is recommended to carry out waterproofing works with indication of discrete exposure intervals in the range of 1085.0-1104.0 m.

Thus, the tool for finding a water well in an existing fund is to evaluate, for each well, the values of the vapor phase, velocity, flow rate of the gas stream, the selection of droplet water in it with the selection of a group of wells with exceeding the current estimated values of the vapor phase and their calculated values (W0 .6 = A / P + B), a change in speed, flow rate, relative to the planned values, followed by monitoring of this group of wells to determine the well water cutter. In a water well, the method of nuclear geophysics (a comprehensive CISK-Sh device) is determined through the density characteristics - the current filtration-capacitive properties (FES) of the section; lithology; the nature of saturation (gas, water, gas + water); intervals of formation water in a heterogeneous thin-layered system of the productive stratum, that is, they carry out current diagnostics of the model of the production object.

Claims (1)

A method for detecting water wells and water supply intervals in it, including conducting without stopping the wells background and monitoring hydrometric studies of the entire existing stock, on the basis of which a group of wells, possible water cutters are identified, then an increment of the vapor phase, speed and flow rate is recorded by the depression on the well gas flow in one direction or another or the absence of increments, on the basis of which a well-waterer is identified in which nuclear research is carried out anija for detecting flooding interval or intervals for several of them wellwork for water shutoff in order to increase the coefficient of gas extractability.

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