RU2778633C1 - Method for conducting induction gamma-neutron logging in a well with high fluid loss and restrictions on the operation of a small diameter string - Google Patents

Abstract

FIELD: oil industry.

SUBSTANCE: invention relates to the oil industry and can be used in preparing a well and conducting a geophysical study of induction gamma-neutron logging (IGN) along the tubing string in conditions of high absorption of previously discovered development objects in small diameter wells, with the aim of additional exploration of the development object, determining oil-saturated thicknesses, calculation of hydrocarbon reserves in reservoirs. The substance of the invention lies in conducting geophysical surveys in the well and analyzing the results obtained. Preliminarily, during the current workover of the well, the liquid loss interval is determined, the assembly is lowered into the well on the tubing, including bottom-up: a plug, a packer, a perforated pipe that provides communication between the tubing and the annulus of the production string. The packer is set above absorbing formations, the pipe string and the annulus are filled with process fluid, checked for tightness, the downhole tool is lowered and induction gamma-neutron logging is performed on the well inside the cavity of the tubing. The downhole tool is lowered into the tubing to the bottom of the study interval. Recording of induction gamma-neutron logging begins simultaneously with the rise of the tool to the top of the studied interval at a speed of lifting the downhole tool not more than 120 m/h.

EFFECT: reducing the duration and cost of well repair, as well as expanding the arsenal of technological capabilities of the method for conducting induction gamma-neutron logging in a well with high fluid loss and restrictions on the operation of a small diameter string.

1 cl, 1 dwg

Description

The invention relates to the oil industry and can be used in preparing a well and conducting a geophysical study of induction gamma-neutron logging (IGN) along a tubing string in conditions of high absorption of previously discovered development objects in small diameter wells, with the aim of additional exploration of the development object, determining oil-saturated thicknesses, calculation of hydrocarbon reserves in reservoirs.

Exploration and additional exploration of development objects are periodically carried out at developed oil fields in order to determine oil-saturated thicknesses, study the dynamics of changes in hydrocarbon reserves, evaluate reserves of fields that are at a late stage of development and enhance oil recovery. In practice, a large number of wells have been drilled through intervals that have high fluid losses or are limited to operating with a small diameter string. Under these conditions, it is not rational to drill additional exploration wells. Carrying out induction gamma-neutron logging in the well, where there is a high value of fluid loss in previously perforated or newly discovered reservoir intervals, if necessary, to perform technological operations to complete reservoirs above the existing ones, as well as the need to confirm the presence of oil-saturated thicknesses in order to conduct additional exploration of the development object and stock confirmation is not possible. According to technical characteristics, induction gamma neutron logging can be carried out only in the presence of liquid in the study interval.

Currently, there are operational restrictions on wells equipped with additional small diameter strings, such as 102, 114 mm. Based on this, the oil industry is faced with a problem impossibility carrying out IGN in wells where there is a high value of fluid loss in previously perforated or newly discovered reservoir intervals, if necessary, to perform technological operations to complete reservoirs above the existing ones, as well as the need to confirm the presence of oil-saturated thicknesses in order to conduct additional exploration of the development object and confirm reserves. According to technical characteristics, induction gamma neutron logging can be carried out only in the presence of liquid in the study interval.

In practice, there are three options for carrying out repair work to ensure well logging with a high value of fluid loss in previously perforated or newly exposed reservoir intervals:

- Backfilling with sand, proppant perforated sections of the formations with filling with liquid for well logging with further washing out of the sand bridge.

- Launching the packer device with further undocking of the tubing for temporary isolation of absorbing perforated formations filled with liquid for well logging.

- Descent of the tool through the annulus with a deflated tubing-packer assembly. in wells with a casing string of small diameter, it is not possible to perform studies due to the tool not passing through the annulus.

All options lead to additional tripping operations and require preliminary preparation and ordering of materials and equipment, which in turn leads to an increase in the duration of repairs, deterioration of reservoir properties, failure to achieve the required bottom hole and a decrease in the quality of the studies performed. Also, these works additionally have a negative impact on the production string.

A known method for determining oil-saturated formations, according to which a core is taken and examined in a well, the oil saturation coefficient is determined from the core, complex logging is carried out, the oil saturation coefficient is determined from the logging, the relative coefficient is determined as the ratio of the oil saturation coefficient from the core to the oil saturation coefficient from the logging, well logging curves are analyzed in the terrigenous section of the productive horizon, reservoirs are identified with apparent resistivity according to induction logging less than 3 Ohm⋅m, among the identified layers, layers are selected, in the mineral composition of which, according to the core and sludge, the presence of minerals that reduce the resistivity is noted, and according to the logging data, increased content of conductive elements, for the identified reservoirs, the true value of the oil saturation coefficient is specified by multiplying the oil saturation coefficient from the logging by the relative coefficient, the resulting value is compared with the values of the oil saturation coefficient for weakly oil-saturated and oil-saturated reservoirs and, accordingly, classify this reservoir as weakly oil-saturated or oil-saturated (RF patent No. 2517730, publ. May 27, 2014).

The closest to the proposed invention in terms of technical essence is a method for determining oil-saturated formations, according to which a core is taken and examined and induction logging and neutron gamma logging or neutron neutron logging are carried out, logging curves are analyzed in the roofing part of the productive layer (RF patent No. 2487239, publ. 07/10/2013). At the same time, formations are identified with apparent resistivity by induction logging not more than 6-8 Ohm⋅m and indications on neutron gamma logging or neutron-neutron logging curves that are 85% or less of the values of the underlying formations. Among the identified formations, formations without shale barriers with formations from carbonate oil-saturated rocks and with apparent resistivity values of at least 15 Ohm⋅m according to induction logging are selected. Then, the lithological composition of the identified reservoirs is specified and, if oil-saturated sandstone is present in their composition, a conclusion is made about the terrigenous origin of these reservoirs. Next, the values of the coefficients of porosity, permeability and oil saturation are specified, if the lower boundaries of which are exceeded for a given region, the identified reservoirs are classified as productive.

The disadvantage of the known methods is the impossibility of conducting induction gamma-neutron logging in a well with high fluid loss and restrictions on the operation of a small diameter column for the purpose of additional exploration of the development object, determination of oil-saturated thicknesses, calculation of hydrocarbon reserves in reservoirs. To carry out the study, it will be necessary to isolate the absorbing formations, which will lead to additional operations and require preliminary preparation and ordering of materials and equipment, which in turn leads to an increase in the duration of workover and downtime of the well, as well as to an increase in the negative impact on the existing perforated productive horizons of the well, deterioration of the porosity and permeability properties of conductive rocks, lowering the quality of work performed.

The technical objectives of the proposal are to provide the possibility of conducting induction gamma-neutron logging in a well with high fluid loss and restrictions on the operation of a small diameter column, increase the efficiency of a high-quality geophysical study for the purpose of additional exploration of the development object, determine oil-saturated thicknesses, calculate hydrocarbon reserves in reservoirs, reduce the duration of the current well repair, reducing material costs for additional equipment, as well as expanding the arsenal of technological capabilities of the method.

Technical problems are solved by the method of conducting induction gamma-neutron logging in a well with high fluid loss and restrictions on the operation of a small diameter column, including conducting geophysical surveys in the well and analyzing the results obtained.

What is new is that during the current workover of the well, the liquid loss interval is preliminarily determined, the assembly is lowered into the well on the tubing, including from the bottom up: the packer is set above absorbing formations, the tubing string and the annular space are filled with process fluid, checked for leaks, the downhole tool is lowered into the tubing and induction gamma-neutron logging is performed on the well inside the cavity of the tubing, while recording the induction gamma-neutron logging in the tubing starts simultaneously with the rise of the tool to the roof of the interval under study at a speed of lifting the downhole tool no more than 120 m/h.

The figure shows a general view of the method of conducting induction gamma-neutron logging on a well with high fluid loss and limitations of operation with a small diameter string.

The essence of the method is as follows.

Conducting induction gamma-neutron logging in a well with high fluid loss and limited operation with a small diameter column is performed by a team of geophysicists. Preliminarily, during TRS, well logging methods determine the fluid loss interval 1 in the well. The assembly is lowered into the well on the tubing, including bottom-up: a plug under the tubing 3, a packer 4, a perforated pipe 5, which provides communication between the tubing 2 and the annular cavity of the production string 6. The packer 4 is planted above the absorbing layers 1, filling the tubing string and annulus with process fluid. Check the annular space for tightness. For the descent of the specified layout, the technological packer PRO-YAMO3-YAG3 (M) 114-59-1000-T100-K3 (manufacturer NPF - Oktyabrsky PACKER) is used. Perforated pipe size from 1200 to 3255 mm. As a process fluid, an emulsion with a density of up to 1.18 g/cm ³ is used.

The geophysical party installs a logging hoist 25-40 m from the wellhead so that the axis of the winch is horizontal and perpendicular to the direction at the wellhead; brake and secure the lift. The laboratory is installed 5-10 m from the wellhead. The guide roller (block) is fixed on a special mount, a depth sensor is installed on the guide roller (block), a downhole instrument IGN is connected to the cable lug, for example AINK-45 manufactured by TNG-Group LLC, weighing 25 kg, 3180 mm long, diameter 45 mm (assembly of instruments, template), check its performance on the catwalks, lower the downhole tool into the well.

A downhole tool is a measuring probe 45 mm in size (IGN) 7 contains a fast (14 MeV) neutron emitter, one or two thermal neutron detectors or gamma radiation. Recording point - the middle of the distance between the emitter and the detector, for two-probe devices - the middle of the distance between the detectors. The descent of the downhole tool is carried out inside the tubing cavity and is carried out under the action of the winch drive of the logging hoist, the mass of the cable and the downhole tool to the bottom of the survey interval. Survey interval 8 is determined by the Geological Survey. The logging recording is started and at the same time the instrument is lifted up to the roof of the studied interval. Lifting speed of the downhole tool during logging recording is not more than 120 m/h. After passing the entire interval under study, the logging recording is stopped and the tool is fully lifted from the well.

Pulsed neutron logging is used in cased wells for lithological separation of sections and identification of reservoirs, identification of water- and oil-and-gas saturated formations, determination of the positions of water-oil contact in oil fields with mineralized (more than 20 g/l) formation waters, determination of gas-liquid contacts, assessment of rock porosity, quantitative assessment of initial, current and residual oil saturation, control over the process of testing and development of wells. The results of geophysical surveys are processed by the interpreters of the geophysical service. The main goals are to assess the completeness of the implementation of the declared complex of studies and the possibility of using the measurement results for qualitative and quantitative interpretation. The regulations for the delivery / acceptance of reporting materials (terms, performers) are determined by the enterprise. The data of the IGN studies are entered into the database of the CIS "ARMITS".

The proposed layout and sequence of operations provides well preparation to improve the quality and efficiency of conducting a geophysical study of the IGN along the tubing string when creating conditions for isolating previously discovered development targets in small-diameter wells with high absorption, creating conditions for reducing the duration of repair and material costs, and also allows a method for conducting induction gamma-neutron logging in a well with high fluid loss and restrictions on the operation of a small-diameter column for the purpose of additional exploration of the development object, determination of oil-saturated thicknesses, calculation of hydrocarbon reserves in reservoirs.

The method is performed in the following sequence.

Conducting induction gamma-neutron logging on a well with high loss values and operating limitations of a small-diameter liquid column is performed by a batch of geophysicists. During the preparatory work determine the interval of absorption of fluid 1 in the well. On the tubing with a diameter of 73 mm, the assembly assembled at the wellhead is lowered, including from bottom to top: a plug for tubing 73 mm 3, a PRO-YAMO 4 packer, a perforated pipe with a size of 1200 to 3255 mm and a number of holes from 114 to 342, which are made at a distance of 53 mm from each other 5, providing communication between the tubing 2 and the annulus of the production string 6. The packer 4 is set above the absorbing layers 1. The pipe string and the annulus are filled with process liquid with a density of up to 1.18 g/cm ³ using a cementing unit (TsA-320) and tank trucks (ATs 6-12), check the annulus for tightness. Next, Geophysicists are conducting a study of IGN 7 along the tubing.

The geophysical party installs a logging hoist 25-40 m from the wellhead. The laboratory is installed 5-10 m from the wellhead. The guide roller (block) is fixed on a special attachment point, a depth sensor is installed on the guide roller (block), which provides control of the depth of the descent of the downhole tool, the downhole tool IGN (tool assembly, template) is connected to the cable lug, its performance is checked on the catwalks, the tool is lowered into the well.

The measuring probe of a downhole tool with a size of 45 mm contains a fast (14 MeV) neutron emitter, one or two detectors of thermal neutrons or gamma radiation. Recording point - the middle of the distance between the emitter and the detector, for two-probe devices - the middle of the distance between the detectors. The tool is lowered inside the tubing string and lowered under the action of the winch drive of the logging hoist, the mass of the cable and the downhole tool to the bottom of the survey interval. Survey interval 8 is determined by the Geological Survey. The logging recording is started and at the same time the instrument is lifted up to the roof of the studied interval. Lifting speed of the downhole tool during logging recording is not more than 120 m/h. After passing the entire interval under study, the logging recording is stopped and the tool is fully lifted from the well.

Pulsed neutron logging is used in cased wells for lithological separation of sections and identification of reservoirs, identification of water- and oil-and-gas saturated formations, determination of the positions of water-oil contact in oil fields with mineralized (more than 20 g/l) formation waters, determination of gas-liquid contacts, assessment of rock porosity, quantitative assessment of initial, current and residual oil saturation, control over the process of testing and development of wells. The results of geophysical surveys are processed by the interpreters of the geophysical service. The main goals are to assess the completeness of the implementation of the declared complex of studies and the possibility of using the measurement results for qualitative and quantitative interpretation. The data of the IGN studies are entered into the database of the CIS "ARMITS".

The method of conducting induction gamma-neutron logging on an active well with high fluid loss and restrictions on the operation of a small diameter string along the tubing string provides a simplification of the preparatory work process, performance of work without loss of quality, reduction of the well repair time by 21 hours - 117 thousand rubles. by reducing tripping operations, and eliminating material costs for the cost of the IGGS sealing device - 45 thousand rubles, and also provides an expansion of the arsenal of technological capabilities for conducting induction gamma-neutron logging in a well with high fluid loss and restrictions on the operation of a small-diameter string with the purpose of additional exploration of the development object, determination of oil-saturated thicknesses, calculation of hydrocarbon reserves in reservoirs.

Claims (1)

A method for conducting induction gamma-neutron logging in a well with high fluid loss and limited operation with a small diameter string, including geophysical surveys in the well and analysis of the results obtained, characterized in that during the current workover of the well, the fluid loss interval is preliminarily determined, the assembly is lowered into the well for tubing, including from bottom to top: a plug, a packer, a perforated pipe that provides communication between the tubing and the annulus of the production string, the packer is set above the absorbing layers, the tubing string and the annulus are filled with process fluid, checked for tightness, the downhole tool is lowered into the tubing and induction gamma-neutron logging is performed on the well inside the cavity of the tubing, while the recording of induction gamma-neutron logging in the tubing is started simultaneously with the rise tool to the roof of the interval under study at a speed of lifting the downhole tool no more than 120 m/h.

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