RU2011140616A - METHOD FOR RECOVERING THE OPERATIONAL CONDITION OF OIL AND GAS PRODUCING WELL WITH A HORIZONTAL AND / OR SUBORGORIZONTAL END IN THE OPERATION PROCESS AND A TECHNOLOGICAL COMPLEX FOR IMPLEMENTATION - Google Patents

Abstract

1. A method for recovering the operating state of an oil and gas well with a horizontal and / or sub-horizontal ending during operation, including three stages, the first of which is the delivery of geophysical instruments to the well, with the help of which the geophysical parameters of the well are measured, including measurement within the horizontal part of the wellbore wells, according to which the inflow profile of the studied section of the well is determined with the selection of "non-working" intervals, at the second stage, the sections of the well corresponding to the identified "non-working" intervals of the inflow profile are flushed from technogenic fluids, at the third stage, control measurements of the geophysical parameters of the well are carried out with the determination of qualitative and quantitative characteristics of the debit of the plots identified at the first stage as "non-working".2. The method according to claim 1, characterized in that when "non-working" areas are identified based on the results of geophysical measurements, in accordance with the third stage, the flushing of "idle" areas is repeated. The method according to claim 1, characterized in that the following geophysical parameters are measured to determine the inflow profile of the investigated section of the well: natural radioactivity of near-wellbore rocks, induced radioactivity of near-wellbore rocks, the number of coupling joints and other metal structures of the well string and the distance between them, temperature, pressure, current flow rate along the wellbore, percentage of liquid and gas-water-oil components present, fluid resistivity along the wellbore, coordinates of the

Claims (21)

1. A method for recovering the operating state of an oil and gas producing well with horizontal and / or subhorizontal completion during operation, which includes three stages, the first of which delivers geophysical instruments to the well, using which the geophysical parameters of the well are measured, including measurements within the horizontal part of the wellbore wells, which determine the profile of the inflow of the investigated section of the well with the allocation of "idle" intervals, at the second stage, flush about tons of technogenic liquids of the well sections corresponding to the identified “idle” intervals of the inflow profile, at the third stage, control measurements of the geophysical parameters of the well are carried out with the determination of the qualitative and quantitative characteristics of the debit of the sections identified as “non-working” in the first stage. 2. The method according to claim 1, characterized in that when identifying "idle" sites according to the results of geophysical measurements in accordance with the third stage, the washing of "idle" sites is repeated. 3. The method according to claim 1, characterized in that the following geophysical parameters are measured for determining the inflow profile of the well section under investigation: the natural radioactivity of the near-wellbore rocks, the induced radioactivity of the near-wellbore rocks, the number of coupling joints and other metal structures of the well string and the distance between them, temperature, pressure, current flow rate along the wellbore, percentage of the present liquid and gas-water-oil components, specific resistivity of the fluid along the wellbore with boreholes, wellbore coordinates, high-pressure flow, acoustic noise; the measured parameters determine the actual design of the well and the technical condition of the string, the level of filling the wellbore with liquid in the working and stopped wells, the density of the fluid along the wellbore, reservoir pressure, production rate, annular pressure, bottomhole pressure, bottomhole temperature are calculated from the well, and the working intervals are selected with the determination of the percentage of total flow rate and quantitative parameters with an interval breakdown, the determination of annular flows, while measured and read parameters are displayed visually on the tablet. 4. The method according to claim 1, characterized in that the delivery of geophysical instruments for measuring the geophysical parameters of the well is carried out using an installation with a first column of flexible tubing, equipped with a geophysical cable located inside the flexible tubing, configured to connect to geophysical instruments, while to prevent deformation of the flexible pipe, the latter is filled with process fluid, and flushing of well sections corresponding to the identified idle "intervals inflow profile in the bottom hole of the horizontal / subhorizontal section of the well, is carried out using a second coiled tubing string without cable inside the pipes, configured to connect to the installation with the first coiled tubing string. 5. The method according to claim 3, characterized in that additionally take samples of the well fluid to determine its origin. 6. The method according to claim 4, characterized in that during the delivery of the geophysical equipment the pressure of the process fluid as the coiled tubing is immersed in the well is changed to a value commensurate with the reservoir pressure, while the differential pressure in the string between the coiled tubing and wellhead pressure is maintained in the range values of 90-150 atm depending on the depth of the well. 7. The method according to claim 4, characterized in that as the working fluid use a fluid characterized by a minimum coefficient of thermal expansion, dielectric properties, anticorrosion properties, and not freezing to -60 ° C. 8. The method according to claim 4, characterized in that the transformer oil, diesel fuel, crude oil, or mixtures of these liquids are used as the working fluid. 9. The method according to claim 4, characterized in that for washing the coiled tubing string is lowered to the "idle" section of the well, while first injecting a chemical reagent into the string, which is used as a substance with foaming properties, which reduces the degree of surface tension located in liquid well at least 2 times, and then gaseous nitrogen to ensure the rise from the bottom of the foamed aqueous solution. 10. The method according to claim 9, characterized in that the injected chemical reagent and gaseous nitrogen are taken in a volume corresponding to the volume of filling of the "idle" section of the well before the bottom, the injection rate of the chemical reagent, gaseous nitrogen and the rate of descent of the CT are selected to ensure uniform distribution of the chemical reagent in the idle interval, while the time of the start of the injection of the chemical reagent and gaseous nitrogen into the coiled tubing string is selected depending on the provision of the conditions for the beginning of the output of the chemical reagent from the pipe string when the entrance to the “idle” section of the well is reached, and the beginning of the gaseous nitrogen exit when the bottom of the well is reached, after which the pipe string begins to rise at a minimum speed and continues to pump nitrogen into the bottom-hole zone of the “non-working” section, thereby providing the removal of fluid to the surface of the reservoir. 11. The method according to claim 9, characterized in that the movement of the pipe string along the "idle" section during the injection into the column of a chemical reagent and gaseous nitrogen is carried out at a speed of 3-5 m per min. 12. Technological complex for the recovery of the operating state of an oil and gas producing well with horizontal and / or subhorizontal completion, including at least two mobile units with coiled tubing connected to wellhead equipment with a flare line in accordance with the technological cycle, one of which is designed for geophysical research and delivery of instruments and tools into the well, and the second for washing the bottom of the well; as well as a geophysical station with a set of geophysical instruments connected to the first coiled tubing installation, equipment for flushing "idle" sections of the well, the first installation consisting of a coiled tubing drum, injector with a guide chute (gooseneck), a preventer block, a sealant and a manipulator equipped with a hydraulic drive of an additional high-pressure hydraulic pump to maintain the required pressure of the process fluid in the flexible pipe, At the same time, a geophysical cable for transmitting the data recorded by geophysical instruments is placed in the coiled tubing pipe, and the connection of the geophysical instruments with the coiled tubing string is sealed by means of a transition unit-connector with a special connector - cable lug, the second coiled tubing unit used to flush the bottom-hole part of the well is on a movable platform, for example, a vehicle platform, a drum with a coiled tubing string configured to be connected to a hydraulic system the first installation of coiled tubing and to the equipment for flushing the well. 13. The technological complex according to claim 12, characterized in that the equipment for washing the "idle" sections of the well includes a mobile nitrogen unit, which includes transport containers with liquid nitrogen, a nitrogen convector for converting liquid nitrogen into gaseous, a pumping unit for supplying chemical reagent, a recirculation tank for formation fluid connected to the wellhead through a borehole fluid chucking unit, as well as a pumping unit for loading formation fluid into a transp filling containers for subsequent disposal, while the pumping unit and mobile nitrogen unit are connected via a high pressure manifold through a high pressure manifold to the coiled tubing string of the second coiled tubing unit for flushing the bottom of the well. 14. The technological complex according to claim 12, characterized in that the first and second installations with the coiled tubing string are located parallel and at a distance from each other, ensuring the placement of the flexible pipes of the installations in the injector without dismantling the surface downhole equipment. 15. The technological complex according to claim 12, characterized in that the first and second coiled tubing are located relative to each other with the formation of an angle between their flexible pipes at the point of connection to the wellhead equipment up to 25 °. 16. The technological complex according to claim 12, characterized in that the hydraulic pump of the first coiled tubing installation has an electric drive and is mounted on a subframe in close proximity to the drum with the coiled tubing string and is connected to the drum by a high pressure pipeline. 17. The technological complex according to claim 12, characterized in that the geophysical station is a mobile complex including a geophysical unit, a universal power source for geophysical instruments, a switching unit, an uninterruptible power supply, a plotter. 18. The technological complex according to claim 12, characterized in that the set of instruments for geophysical surveys contains instruments of the PO 50 and SLM brand for recording inhomogeneities of the string and tubing, as well as complex instruments KSAT-43GR and PLT-9.2 for carrying out flowometric studies . 19. The technological complex according to claim 12, characterized in that the set of equipment for flushing the well includes a flushing nozzle, a connector used to connect the coiled tubing string to the flushing nozzle, a check valve block that allows fluid and gas to be injected into the well and preventing the flow of well fluid into Coiled tubing, while the flushing nozzle is made with calibrated holes to create a pressure flow of liquid and gas. 20. The technological complex according to p. 12, characterized in that the connector is made with the possibility of filling in the CT and connecting the pipe to the cable lug, while the cable lug is a part of a prefabricated structure with a central through hole for accommodating the cable and includes a sealant connected to the connector, geophysical cable attachment unit, articulated mechanism designed to give flexibility to the cable lug, cable head made with the possibility of connecting the geophysical instrument. 21. The technological complex according to claim 12, characterized in that the connector is capable of refueling in the CT and connecting the pipe to the cable lug, while the cable lug is a part of a prefabricated structure with a central through hole for accommodating the cable and includes a cable adapter connected to the connector , sealant, single-joint mechanism, cable head, made with the possibility of connecting a geophysical instrument.