RU2222713C1 - Method of operation of pump-ejector impulse well plant - Google Patents

Abstract

FIELD: oil producing industry. SUBSTANCE: invention is designed for testing and completion of wells. According to proposed method, linear hydraulic impulse device, packer and jet pump with stepped through channel mounted in tandem from bottom to top are lowered on tubing string into well, then liquid medium is delivered into hydraulic impulse device and bottom hole zone of productive stratum is treated with said medium by hydraulic impulse cavitation with subsequent pumping out said medium by means of jet pump from under- packer space of well together with colmatating particles and lifting the medium to surface. Hydraulic impulse device is made sectional, consisting of stationary part installed on tubing string lower than packer and in which stepped through channel is made along axis of tubing string, and lowering down part made in form of insert. Before treatment of bottom hole zone of productive stratum, field- geophysical researches of productive stratum are carried out in operating well by lowering radiator and receiver-converter of physical fields through stepped channel of jet pump and stepped through channel of stationary part of hydraulic impulse device, and after treatment of bottom hole zone of productive stratum and before pumping out liquid medium with colmatating particles, productive stratum is subjected to treatment with chemical reagents by pumping the reagents into well along tubing string through jet pump and stationary part of hydraulic impulse device, with interlocking inserts with central longitudinal through channel being installed in stepped through channels. After chemical treatment of productive stratum, field-geophysical researches are carried out again in working well and curves of pressure built-up by means of functional insert installed in stepped through channel of stationary part of hydraulic impulse device or in stepped through channel of jet pump are recorded. EFFECT: enlarged functional capabilities of plant, improved efficiency of studies and treatment of bottom hole zone of productive stratum. 4 dwg

Description

The invention relates to the field of inkjet technology, mainly to downhole installations for testing and development of wells.

A known method of operation of a pump-ejector well installation, comprising supplying an active liquid medium to a nozzle of a jet apparatus through a pipe string, pumping a passive medium from a formation zone of a jet apparatus and supplying a mixture of media from the well to the surface (see USSR author's certificate 1100436, class F 04 F 5/02, 06/30/1984).

However, this method of operation of the installation does not have the ability to exert any effect on the near-wellbore zone of the reservoir, which drastically reduces the possibility of using the installation working on this method.

The closest to the invention in terms of technical nature and the achieved result is a method of operating a pump-ejector borehole pulse installation, which consists in lowering into the well on a pipe string installed sequentially from the bottom up, a funnel, a hydraulic pulse device, a packer and a jet pump with a stepped passage channel , the liquid medium is supplied to the hydro-pulse device and treated with this medium in the hydro-pulse cavitation mode, the borehole zone of the reservoir, followed by pumping with p with the help of a jet pump from a sub-packer zone of a well of a liquid medium together with clogging particles to the surface (patent RU 2143600, class F 04 F 5/54, 12/27/1999).

This method of operation of the installation allows the processing of the borehole zone of the reservoir using a hydro-pulse device. However, in this method of operation of the installation, the possibilities for conducting a well study are limited, both before the processing of the near-wellbore zone and after its processing, which is associated with the need to remove the pipe string from the well so that the well can be explored below the level of the hydraulic pulse device in the well.

The problem to which the present invention is directed, is to expand the functionality of the installation method and increase the efficiency of ongoing research and processing of the borehole zone of the reservoir.

This problem is solved due to the fact that the method of operation of the pumping and ejection borehole pulse installation consists in lowering the liner, a liner, a water pulse device, a packer and a jet pump with a stepped passage channel, installed sequentially from the bottom up, and supplying the liquid medium to hydraulic pulse device and process this medium in a hydraulic pulse cavitation mode, the borehole zone of the reservoir, followed by pumping from the sub-packer zone of the well using a jet pump the liquid medium together with colmatizing particles to the surface, while the water-pulse device is assembled and consists of a stationary part, which is installed on the pipe string below the packer and in which a stepped passage channel is made along the axis of the pipe string, and the drain part, which is made as an insert, Before processing the near-wellbore zone of the reservoir, field geophysical studies of the reservoir in a working well are carried out: by passing the emitter and receiver-converter fields through the stepped passage channel of the jet pump and the stepped passage channel of the stationary part of the hydraulic pulse device, and after processing the borehole zone of the reservoir before pumping out the liquid medium with colmatizing particles, the reservoir is treated with chemical reagents by pumping them into the well through the pipe string through the jet pump and stationary part of the hydroimpulse device, moreover, in the stepped passage channels of the latter, blocking inserts are pre-installed ki with a central longitudinal passage channel, and after chemical treatment of the productive formation, repeated field-geophysical studies are carried out in a working well and the formation pressure recovery curves are recorded using a functional insert installed in the stepped passage channel of the stationary part of the hydro-pulse device or in the stepped passage channel of the jet pump.

An analysis of the work being carried out in the well to study and process the borehole zone of the reservoir showed that all these work can be carried out without removing the pipe string to the surface, which can significantly exceed the effectiveness of the research. This was achieved primarily due to the fact that the jet pump body, and the packer, and the hydro-pulse device are made with a central passage channel, which allows for the descent and installation of various types of equipment in the productive formation zone, for example, a perforator or source and receiver -transformer of physical fields. Moreover, the implementation of the hydroimpulse device as a component, consisting of two parts - stationary and descent, made it possible to use the stationary part to place various kinds of equipment in it, for example, a functional insert for recording formation pressure recovery curves. For this, in the stationary part of the hydraulic pulse device, the central passage channel is made in the form of a stepped passage channel, which makes it possible to install and fix the above equipment in the stationary part of the hydraulic pulse device. The rational use of the cross section of the pipe string is essential to ensure, as far as possible, the minimum possible hydraulic resistance for the fluid pumped out of the well and at the same time to allow the installation of various kinds of functional inserts both in the stepped passage channel in the jet pump housing, and in the stepped passage channel of the stationary part of the hydro-pulse device. At the same time, the functional insert, which is intended for installation in the stationary part, should not get stuck in the jet pump housing when it is lowered along the pipe string. This was achieved under the condition that the diameter of the lower stage of the passage channel of the stationary part of the hydraulic pulse device is less than the diameter of the lower stage of the passage channel of the jet pump.

Thus, the method of operation of the pump-ejector unit described above provides the possibility of conducting complex studies of the reservoir and the well as a whole and makes it possible to process the borehole zone of the reservoir by various methods, including hydro-pulse treatment, ultrasonic treatment and acid treatment of the borehole zone of the reservoir.

Figure 1 shows a longitudinal section of the installation with the transmitter and receiver installed in the well of the transmitter of the physical fields; figure 2 presents a longitudinal section of the installation before the start of the hydro-pulse processing with the assembled hydro-pulse device and a blocking insert in the housing of the jet pump; figure 3 presents a longitudinal section of the installation with blocking inserts installed in both step through channels; figure 4 presents a longitudinal section of the installation with a depressive insert in the stepped passage channel of the jet pump and an insert for recording the recovery curves of reservoir pressure in the stepped passage channel of the stationary part of the hydraulic pulse device.

Installation for implementing the method of operation of the pump-ejector well borehole installation includes mounted on the pipe string 1 bottom-up shank 2 with an inlet funnel 3, a pulse train 4, a packer 5 and a jet pump 6, in the housing 7 of which an active nozzle 8 and a mixing chamber 9 are installed with a diffuser, and also a channel for supplying the active medium 10, a channel for supplying the medium 11 pumped out from the well and a step-through channel 12 are made, and the latter provides for the possibility of installing interchangeable functional inserts: I block 13 with a through passage channel 14 and a depression 15. The active nozzle 8 is blocked by the blocking insert 13 from the input side thereof when installing the latter and is open for supplying an active medium when the depression insert 15 is installed, and this insert, when installed, has a cross section of the column pipes 1. Packer 5 is made with a central channel 16, the hydro-pulse device 4 consists of two parts: stationary 17 and deflated 18. In the stationary part 17 installed on the pipe string 1 below the packer 5, a two-stage passage to anal 19 with the possibility of passing through it fixed on a logging cable or wire 20 instruments and devices for research and processing of a productive formation, for example, a perforator (not shown) or emitter and receiver-transducer of physical fields 21, and installation in it made in the form of a descent insert parts 18 of the hydro-pulse device 4 and interchangeable functional inserts for research and processing of the reservoir and formation fluid, the latter and the descent part 18 of the hydro-pulse device 4 made with POSSIBILITY their passage through the stepped passageway 12 of the jet pump 6 and the central channel 16 of the packer 5 and the diameter D _1, the lower-stage flow channel 19, the fixed portion 17 hydroimpulse device 4 is less than the diameter D ₂ a lower-stage flow channel 12 of the jet pump 6. The fixed part 17 water-pulse device made nozzle holes 22 for processing the bottom-hole zone of the reservoir 23. When you install in the well of the emitter and receiver-transducer of physical fields 21 on a wireline or wire 20 along the sealing unit 24 is movably disposed, which is installed in the stepped passage channel 12 of the housing 7 of the jet pump 6. In addition, in the stepped passage channel 19 of the hydraulic pulse device 4, it is possible to install a blocking insert 25 with a central passage channel 26 and to insert registration of reservoir pressure recovery curves 27.

The method of operation of the pump-ejector borehole pulse installation consists in lowering a liner 2, successively installed from the bottom up, to a liner 2 with an inlet funnel 3, a pulse train 4, a packer 5 and a jet pump 6 with a stepped passage channel 12. Inlet funnel 3 positioned above the top of the reservoir 23. Unpack the packer 5. Unpack the logging cable or wire 20 into the well of the emitter and receiver-transducer of physical fields 21 and placed movably on the logging the cable or wire 20, the sealing unit 24. In this case, the sealing unit 24 is installed in the stepped passage channel 12, and the emitter and the receiver-converter of the physical fields 21 are passed through the stepped passage channel 12 of the jet pump 6, the central channel 16 of the packer 5 and the stepped passage channel 19 of the hydraulic pulse devices 4 and are located in the zone of the reservoir 23. In this case, field geophysical studies of the reservoir are carried out, including measurements of the background values of physical fields and flow rate parameters of the reservoir ASTA 23. Moreover, the flow rates are measured at different depressions on the reservoir 23, which are created by feeding the working agent into the active nozzle 8 of the jet pump 6. In addition, the parameters of the formation fluids are measured. During the measurements, the emitter and receiver-transducer of physical fields 21 are moved along the wellbore, while recording the inflow profile and parameters of formation fluids from various layers of the productive formation 23. Based on the results of the above-mentioned geophysical study, the intervals of poorly functioning and non-working layers are determined, which require cleaning of their borehole zone. The emitter and receiver are removed from the physical field transducer 21 together with the sealing unit 24 and the wireline or wire 20 from the well and the packer 5 is depacked. By moving the pipe string 1, the stationary part 17 of the hydro-pulse device 4 against the interlayer to be processed is installed. Install a descent part 18 in the stepped passage channel 19 of the stationary part 17 of the hydro-pulse device 4, and a blocking insert 13 in the stepped passage channel of the jet pump 6. The liquid medium is supplied to the hydro-pulse device 4. The liquid flowing out of the nozzles 22 of the hydro-pulse device 4 exerts a hydro-pulse cavitation impact on the borehole zone of the treated layer of the reservoir 23. Similarly, moving the hydro-pulse device 4 along the reservoir 23, produce the work of other layers of the reservoir 23. After that, the blocking insert 13 and the descent part 18 of the hydro-pulse device 4 are removed to the surface and the blocking inserts, 13 and 25, respectively, are installed in the stepped passage channel 12 of the jet pump by the stepped passage channel 19 of the stationary part 17 of the hydro-pulse device 4. which protects the jet pump 6 and the stationary part 17 from corrosion. Injection through the pipe string 1 through blocking inserts 13 and 25 of a solution of chemical reagents is carried out and pushing it into the reservoir 23. Then, blocking inserts 13 and 25 are removed to the surface and the depressant insert 15 is installed in the stepped passage 12 of the jet pump 6.

After the estimated reaction time of the chemical reagents has elapsed, by applying the working agent to the active nozzle 8 of the jet pump 6, a depression is created on the reservoir and thus the reaction products and products of hydro-pulse treatment are pumped out of the reservoir 23 and from the well. After that, re-exploration and geophysical studies are carried out with a control measurement of the well flow rate at various depressions on the reservoir 23. It is possible (if necessary) to conduct a second study of the inflow profile and record the pressure recovery curves by installing a stationary part 17 of the hydraulic pulse device in the stepped passage channel 19 4 inserts for registration of reservoir pressure recovery curves 27. A similar insert can be installed in a stepped passage th channel 6 of the jet pump 12 instead of the depression 15. As a result of the insertion repeated study may conduct additional impact on the producing formation 23, e.g., through the perforations 23 of the producing formation or effect on the reservoir 23 by ultrasound.

The present invention can be used in the oil and gas industry during the development and repair of wells.

Claims (1)

The method of operation of the pump-ejector borehole pulse installation, which consists in lowering the liner, a liner, a water pulse device, a packer and a jet pump with a step-through channel, installed sequentially from the bottom up, feeds the liquid medium into the hydraulic pulse device and processes it in hydraulic pulse cavitation mode, the borehole zone of the reservoir with subsequent pumping using a jet pump from the sub-packer zone of the well of a liquid medium together with and particles to a surface, characterized in that the water-pulse device is assembled and consists of a stationary part, which is installed on the pipe string below the packer and in which a stepped passage channel is made along the axis of the pipe string, and a drain part, which is made as an insert, before processing field geophysical studies of the reservoir in a working well by passing the emitter and receiver-transducer of physical fields through the pass the bottom stepped channel of the jet pump and the stepped passage channel of the stationary part of the hydraulic pulse device, and after processing the borehole zone of the reservoir before pumping out the liquid medium with colmatizing particles, the productive formation is treated with chemical reagents by pumping them into the well through a pipe string through the jet pump and the stationary part of the hydraulic pulse device moreover, in the stepped passage channels of the latter, blocking inserts with a central longitudinal are pre-installed m through passage channel, and after chemical treatment of the producing formation, repeated field-geophysical studies are carried out in a working well and the formation pressure recovery curves are recorded using a functional insert installed in the stepped through passage of the stationary part of the hydro-pulse device or in the stepped through passage of the jet pump.

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