RU2208714C1 - Method of operation of well jet unit at hydrodynamic study of wells - Google Patents

Abstract

FIELD: hydrodynamic study of wells. SUBSTANCE: proposed method includes mounting inlet funnel, packer and jet pump and lowering this assembly into well through string; then, packer is released and radiator and receiver- transducer are lowered into well; in the course of lowering, background measurements of temperature and other physical fields are performed and drainage of stratum is carried out recording bottom-hole pressures, composition and physical parameters of fluid fed from productive stratum, as well as well production rate; productive stratum is acted on by physical fields, thus cleaning the near-well zone of productive stratum from colmatage particles and filtrate of drilling mud and cement slurry; then profile of formation fluid inflow is recorded and insert is lowered into well for recording pressure-build-up curves in under-packer space with sampler and self-contained pressure gauge and preset depression is formed in under-packer space which is maintained during definite period of time; volume of formation fluid fed from productive stratum during this period of time is measured and pressure-build-up curve is recorded. EFFECT: enhanced operational reliability; increased productivity. 2 dwg

Description

 The invention relates to the field of pumping technology, mainly to downhole pumping units for oil production from wells.

 A known method of operating a jet downhole installation, comprising supplying an active liquid medium to a nozzle of a jet apparatus through a tubing string, entraining a passive medium with it and mixing with it to supply a mixture of media from the well to the surface (see RU 2059891 C1, F 04 F 5 / 02, 05/10/1996).

 This method of operation of a downhole jet installation allows pumping out various produced media, for example, oil, from a well while processing the produced medium and the borehole zone of the formation, however, this method does not provide for the possibility of selective action on the borehole formation zone, which in some cases narrows the scope of this way of working.

 The closest to the invention in terms of technical nature and the achieved result is a method of operating a downhole jet installation, comprising installing a jet pump in a well on a tubing string located in a housing with a passage made in the last passage channel, supplying a working medium through the tubing string to the nozzle of the jet pump and creating due to this in the sub-packer zone of controlled pressure with the possibility of draining the formation and other routine maintenance (see patent RU 2176336 C1, class F 04 F 05/02, 11/27/2001).

 This method of operation of a downhole jet installation allows the formation to be processed in a well below the level of the jet pump installation, including creating a pressure differential above and below the sealing unit. However, this method of operation does not allow full use of the capabilities of a downhole jet installation, which is associated with a limited set of operations for treating a formation, mainly using chemically active liquid media and the lack of an optimal sequence of steps for investigating the state of a productive formation.

 The problem to which the present invention is directed, is to improve the quality of the study of the reservoir and, due to this, to obtain a more objective picture of its condition and to develop a well-thought-out sequence of actions to restore the permeability of the borehole zone of the reservoir.

 This problem is solved due to the fact that the method of operating a well jet device during hydrodynamic research of wells consists in installing an inlet funnel with a liner, a packer and a jet pump from the bottom up, in the housing of which there is a channel for supplying an active medium, a channel for supplying pumped medium from a well and a stepped passage channel with a seat between the steps, lower this assembly on the pipe string into the well, while the inlet funnel is located not lower than the roof of the reservoir, then p packing the packer and then lowering the emitter and the receiver-transformer of physical fields together with a sealing assembly, which is placed on the logging cable or wire above the tip for connecting the emitter and receiver-transformer of physical fields and installed on the landing, through the passage channel of the jet pump housing on the logging cable a place in the passage channel of the jet pump housing with the possibility of reciprocating movement of the wireline cable or wire through the seal the measuring unit, during descent, background measurements of temperature and other physical fields along the wellbore from the funnel to the bottom of the well are carried out, then the emitter and receiver-converter of physical fields are mixed over the top of the reservoir and, under pressure, a liquid medium is pumped into the active nozzle of the jet pump formation with the phased creation of at least three successively increasing depth values of depression per formation, recording downhole pressures, composition and physical parameters with each of them Fluids coming from the reservoir, as well as the flow rate of the well, then effect physical fields on the reservoir in the mode of simultaneous exposure to at least one of the three values of depression or instantaneous cyclic depressions - repressions created with the help of a jet pump by instantaneous supply into the nozzle of the working fluid and the instantaneous cessation of its supply, thus cleaning the near-wellbore zone of the reservoir from the particles that clog it, the drilling filtrate and solution of water, then record the profile of formation fluid inflow with a fixed value of depression on the formation, then stop supplying liquid medium to the jet pump, remove the emitter and receiver-converter of physical fields from the well together with a wireline or wire and a sealing assembly, then lower it into the well along the pipe string and an insert is installed on the seat for recording the reservoir pressure recovery curves in the under-packer space with a sampler, an autonomous pressure gauge or a pressure sensor connected to the recording device on the surface using a wireline cable, create a predetermined depression value on the reservoir in the sub-packer space, maintain this depression value for a predetermined time, measure the volume of reservoir fluid received from the reservoir during this time, then abruptly stop the flow working fluid in the nozzle of the jet pump and record the recovery curve of reservoir pressure in the under-packer zone, after which create a deeper depression on the prod the reservoir, maintain this depression value for a predetermined time, measure the volume of reservoir fluid received from the reservoir during this time, then the flow of working fluid into the nozzle of the jet pump is abruptly stopped, and the reservoir pressure recovery curve in the sub-packer zone is recorded, and the number of such measurements of reservoir recovery curves the pressure must be at least two, then rise to the surface of the insert to record the curves for the restoration of reservoir pressure, lower into the well the column of pipes emitter and receiver-converter of physical fields with installation on a seat in the passage channel of the sealing unit and record the flow rates and physical parameters of the reservoir fluid with at least three values of depression on the reservoir, as well as record the profile of the influx of reservoir fluid at specified values of depression, and then the emitter and the receiver-converter of physical fields are removed from the well to the surface.

 An analysis of the operation of a downhole jet installation has shown that the reliability and effectiveness of hydrodynamic studies can be improved by optimizing the sequence of actions when conducting the above studies of a productive formation using combined exposure of the formation to physical fields and the creation of various depressions on the formation.

 It was found that the above sequence of actions allows the most efficient use of a downhole jet unit in combination with a transmitter and receiver with a physical field transducer, which ultimately allows to intensify the flow of oil from the reservoir. By examining the reservoir both before and during the hydrodynamic impact on the reservoir, it is possible to first assess the actual technical condition of the well, the properties of the fluid produced from the well, the state of the near-well zone of the productive formation and select the operating mode of the jet installation in combination with the impact on the productive layer by physical, for example temperature, electromagnetic, ultrasonic and other fields. In the course of the work, it is possible to evaluate the effectiveness of the ongoing study of the reservoir and choose the most effective mode for continuing the study of the well. The alternating hydrodynamic effect on the formation in combination with the impact on the formation of physical fields can increase the reliability of the information received about the potential productivity of the formation. With the created depression, the jet pump promptly removes clogging particles from the reservoir, which are brought to the surface with high speed. The use of the receiver-converter of physical fields and functional inserts, including stand-alone devices that can be installed under the functional inserts, allows the study of the medium coming from the well and the physical parameters of the formation. At the same time, it is possible to visually control the magnitude of depression, receiving information from the above stand-alone instruments and instruments that are installed on a wireline about the current hydrostatic pressure. It was found that a step-by-step transition from depression to formation to repression with cyclic repetition of this operation and optimization of the stepwise mode of creating depression on the formation are essential for effective stimulation of the formation. It was also revealed the minimum number of these cycles of hydrodynamic effects on the reservoir, which should be at least 3 in order to achieve high-quality cleaning of the borehole zone of the reservoir and to obtain more reliable and diverse information about the reservoir and the well as a whole .. During the study, the emitter was allowed to move and the receiver-transducer of physical fields along the well, and the study of the reservoir and its processing can be carried out as with a working jet Sosa, and when it is stopped (if necessary). Thus, this method of operation allows for intensive research of wells and their testing in various modes. As a result, it was possible to speed up the work to increase well productivity by 1.2-1.6 times, while conditions are created for leveling the profile of formation fluid inflow. It should be noted that the sequence of actions described in the invention allows you to constantly monitor the progress of the hydrodynamic study of the well. In particular, the obtained inflow profiles and reservoir pressure recovery curves provide an objective picture of the state of the near-wellbore zone of the reservoir, depending on the work carried out in the well.

 Thus, the achievement of the task is achieved - improving the reliability and productivity during the hydrodynamic study of the well.

 In FIG. 1 shows a longitudinal section of a downhole jet installation for implementing the described method of operation with a sealing assembly installed therein; figure 2 is a longitudinal section of the installation with a functional insert for recording the curves of the restoration of reservoir pressure in the under-packer space with a sampler installed underneath and a stand-alone device.

 The downhole jet installation comprises an inlet funnel 2 with a liner 3 mounted on the pipe string 1 from bottom to top, a packer 4 with a central channel 5 made therein, and a jet pump 6, in the housing 7 of which an active nozzle 8 and a mixing chamber 9 are installed, as well as an inlet channel active medium 10, the channel 11 for supplying the medium pumped out from the well and a step-through passage channel 12 with a seat 13 between the steps, while in the step-through passage channel 12 it is possible to install a sealing assembly 14, which is movably located on the logging cable 15 above the tip 16 for connecting the emitter and the receiver-transducer of the physical fields 17. In addition, in the stepped passage channel 12, it is possible to install a functional insert 19 for recording the reservoir pressure recovery curves in the under-packer space of the well together with a sampler 20 and an autonomous device 21 equipped with, for example, sensors for pressure, temperature, flow rate and composition of the reservoir fluid. The output of the jet pump 6 is connected to the annulus of the well (pipe string 1), the nozzle 8 of the jet pump 6 is connected through the channel for supplying the active medium 10 to the inner cavity of the pipe string 1 above the sealing unit 14, and the channel 11 for supplying the medium pumped out of the well is connected to the internal cavity pipe string 1 below the sealing unit 14, and a functional insert is made in the upper part with the device 22 for its installation and removal from the well.

 The method of operation of a downhole jet installation during hydrodynamic research of wells consists in installing an inlet funnel 2 with a liner 3, a packer 5 with a central channel 5 and an jet pump 6, in the housing 7 of which an active medium supply channel 10 is made, and a supply channel for pumping out wells of medium 11 and a stepped passage channel 12 with a seat 13 between the steps. This assembly is lowered on the pipe string 1 into the well, while the inlet funnel 2 is positioned no lower than the top of the reservoir 23. The packer 4 is unpacked and then lowered into the well through the passage channel 12 of the housing 4 of the jet pump 6 on the wireline 15 transmitter and receiver-transducer physical fields 17 together with a sealing assembly 14, which is placed on the logging cable 15 above the tip 16. The sealing assembly 14 is installed on the seat 13 in the passage channel 12 of the housing 7 of the jet pump 6, with the possibility of the reciprocating movement of the logging cable 15 through the sealing unit 14. During the descent, background measurements of temperature and other physical fields along the wellbore from the input funnel to the bottom of the well are carried out. Next, the emitter and receiver-converter of physical fields 17 are stirred over the roof of the productive formation 23 and by supplying a liquid medium to the active nozzle 8 of the jet pump 6, drainage of the formation 23 is carried out with the phased creation of at least three successively increasing depth values of depression on the formation 23, registering at each of them bottomhole pressures, composition and physical parameters of the fluid coming from the reservoir 23, as well as the flow rate of the well. Next, physical fields are applied to the reservoir 23 in the mode of simultaneous exposure to at least one of the three depression values or instant cyclic depressions-repressions created by the jet pump 6 by instantly supplying the working fluid to the nozzle 8 and stopping its flow, thus cleaning the near-wellbore zone of the producing formation 23 from the particles that clog it, the filtrate of the drilling and cement solutions. Then, the profile of the formation fluid inflow is recorded with a fixed depression on the formation 23, the flow of liquid medium to the jet pump 6 is stopped, the emitter and the receiver-transducer of physical fields 17 are removed from the well together with the wireline cable 15 and the sealing assembly 14. Then they are lowered into the well along the column pipes 1 and install on the seat 13 insert 19 for recording the curves of reservoir pressure recovery in the under-packer space with a sampler 20 and an autonomous pressure gauge or pressure sensor 21 associated with with a recording device on the surface using a wireline cable 15. Create a predetermined depression value on the reservoir 23 in the under-packer space, maintain this depression value for a predetermined time, measure the volume of reservoir fluid received from the reservoir during this time, and then sharply stop the flow of working fluid into the nozzle 8 of the jet pump 6 and register the recovery curve of reservoir pressure in the under-packer zone. After that, a deeper depression is created on the reservoir 23, this depression is maintained for a predetermined time, the volume of the reservoir fluid received from the reservoir 23 is measured during this time, and then the flow of the working fluid into the nozzle 8 of the jet pump 6 is abruptly stopped and the recovery curve of the reservoir pressure is recorded in the sub-packer zone, and the number of such measurements of the reservoir pressure recovery curves should be at least two. Then make the rise on the surface of the insert 19 to record the curves of the restoration of reservoir pressure, lower the emitter and the receiver-transducer of physical fields 17 into the well through the pipe string 1 with installation of the sealing assembly 14 in the passage channel 12 and record the flow rates and physical parameters of the formation fluid with at least three values of depression on the reservoir 23, as well as recording the profile of the influx of reservoir fluid at given values of depression. Then, the emitter and the receiver-converter of physical fields 17 are removed from the well to the surface.

 The present invention can be used in the oil and gas industry when testing geological objects, developing wells after drilling, or when repairing them underground in order to intensify hydrocarbon production.

Claims (1)

 The method of operation of a well jet device during hydrodynamic research of wells, which consists in installing an inlet funnel with a liner, a packer and a jet pump, from the bottom of which an active medium supply channel, a medium supply channel for pumping out of the well and a stepped passage channel with a seat are installed between the steps, lower this assembly on the pipe string into the well, while the inlet funnel is positioned no lower than the top of the reservoir, then the packer is unpacked and then lowered into on the wireline of the jet pump housing on the wireline cable, the transmitter and the receiver-converter of physical fields together with a sealing assembly that is placed on the wireline or wire above the tip to connect the transmitter and receiver-converter of the physical fields and installed on a seat in the passageway of the housing of the jet pump with the possibility of reciprocating movement of the wireline or wire through the sealing unit, in the process of descent wire t background measurements of temperature and other physical fields along the wellbore from the funnel to the bottom of the well, then the emitter and receiver-converter of physical fields are placed over the top of the productive formation and by supplying a liquid medium to the active nozzle of the jet pump, the formation is drained with a phased creation of at least of three successively increasing depth values of depression per reservoir, recording bottomhole pressures, composition and physical parameters of fluid coming from a productive one at each of them the reservoir, as well as the flow rate of the well, then effect physical fields on the reservoir in the mode of simultaneous exposure to at least one of the three values of depression or instant cyclic depressions-repressions created with the help of a jet pump by instantly supplying working fluid to the nozzle and instant termination of its supply, thus cleaning the near-wellbore zone of the reservoir from clogging particles, filtrate of drilling and cement slurries, then record l the formation fluid inflow profile with a fixed depression on the formation, then the liquid medium is stopped flowing to the jet pump, the emitter and the receiver-transducer of physical fields are removed from the well together with the wireline or wire and the sealing assembly, then they are lowered into the well along the pipe string and installed on insert for recording reservoir pressure recovery curves in the under-packer space with a sampler, autonomous pressure gauge or pressure sensor associated with the recording device on the surface using a wireline cable, create a predetermined amount of depression on the reservoir in the under-packer space, maintain this amount of depression for a predetermined time, measure the volume of formation fluid received from the reservoir during this time, then sharply stop the flow of working fluid into the nozzle of the jet pump and record the pressure recovery curve in the sub-packer zone, then create a deeper depression on the reservoir, maintain this value of the depression and a predetermined time, the volume of formation fluid received from the reservoir during this time is measured, then the flow of the working fluid into the jet pump nozzle is cut off and the recovery curve of the reservoir pressure in the sub-packer zone is recorded, and the number of such measurements of the reservoir pressure recovery curves must be at least 2 , then lift to the surface of the insert to record the curves of reservoir pressure recovery, lower the emitter and receiver-transmitter f into the well along the pipe string fields to be installed at a seat in the passage channel of the sealing unit and record the flow rates and physical parameters of the formation fluid with at least three values of depression on the reservoir, as well as record the profile of the influx of formation fluid at the specified values of depression, and then extract it from the well to the surface emitter and receiver-converter of physical fields.

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