RU2404360C1 - Well operation method - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: method involves installation of ground receiving and production equipment on the mouth, perforation and development of wells, installation of electric divider (ED), lowering of well measurement equipment (WME) with installed measuring electrodes (ME) to production casings (PC), hydrodynamic and geophysical investigations and transfer of information to the surface by means of well dipole. At that, the number of PC is chosen not more than two, which are connected to each other with electrical conductor and PC of wells with production equipment are connected at least on one side of the well PC, which allows installing logging cable and having WME which has contact to ground receiving equipment. ME and housing with WME, which is connected to PC, serve as well dipole. Electrically, divider is installed on WME, and PC has stable electrical contact to formation water. Besides electrical conductor is equipped with filtration device allowing the signals laying in information bandwidth.

EFFECT: simplifying the way of obtaining hydrodynamic and geophysical information on each object in any wells with minimum information errors.

2 cl, 3 dwg

Description

The invention relates to techniques for hydrodynamic and geophysical measurements in wells participating in the hydrocarbon production process, and is intended to control the depth parameters during the operation of the wells and transfer the recorded parameters to the surface. The solutions proposed in the patent are primarily aimed at promptly obtaining information on each object in wells that reveal several productive intervals.

A known method of operating wells, in particular oil and gas, including wellhead and bottomhole equipment, perforation and development, lowering the downhole tool into the production string and conducting hydrodynamic and geophysical studies (see Zhukov A.I., Chernov B.S. and Bazlov M .N Oil exploitation. Gostoptekhizdat, 1961).

The disadvantage of this method is the discreteness of obtaining hydrodynamic and geophysical information during the operation of the well. As a rule, studies are carried out interrupting the production of oil or gas and using a cable communication channel or autonomous recording of parameters with subsequent decoding after removing the device from the well. An electric screen in the form of a casing string does not allow exploring the near-wellbore space using electric or electromagnetic logging methods. The difficulty of obtaining hydrodynamic and geophysical information in real time during the production of hydrocarbons, especially from a multilayer reservoir, does not allow for efficient management of well operation.

Known downhole telemetry system (US Pat. RF №2161701). This system contains an electric separator, a non-magnetic insert, an in-depth unit with zenith angle and azimuth sensors and a power source, as well as a ground receiving complex. The system uses an electromagnetic communication channel to transmit information from the bottom to the surface. The disadvantage is the inability to use the system to transmit a signal through shielding layers with high conductivity.

A known method and device for monitoring downhole parameters in shielding formations with high conductivity (RF patent No. 2193655). The method includes exciting an electric field using a sinusoidal voltage generated by a downhole turbogenerator. During the operation of the downhole telemetry system transmitter with a wireless electromagnetic communication channel, electrical logging is carried out with the determination of the electrical resistance of the medium characterizing the drilling formation. During operation of the downhole telemetry system transmitter with a wireless electromagnetic communication channel, the voltages applied to the electrical splitter are measured. The device comprises an antenna connected by a cable to the ground receiving and processing equipment, a downhole tool with measuring primary transducers, a transmitter, a power source, and an electrical splitter that acts as a dipole formed as a result of the electrical separation of the drill string. In addition, the system includes an additional electrical splitter made above the high conductivity shielding formation, and a cable connecting the transmitter to this electrical splitter to ensure the system is operational when the transmitter is below the high conductivity shielding formation. The disadvantages of the system are that it is necessary to install the cable in the drill pipe string and constantly expand it during drilling, and the additional electric separator to be constantly reinstalled in the drill pipe string, this complicates the operation and may lead to a failure in signal transmission due to the cable made integral and contains many contact points.

The known method and device (US Pat. US No. 61777882). The method includes measuring downhole parameters using a downhole telemetry system and transmitting them to an antenna connected to ground receiving and processing equipment, in which the antenna is installed below the high conductivity shielding layer. The device comprises an antenna connected to ground receiving and processing equipment, a downhole tool with measuring primary transducers, a power source and an electric splitter that acts as a dipole as a result of electrical separation of the drill string, in which the antenna is installed below the high conductivity shielding formation.

There is a method that provides for the use for monitoring the production process of two or more downhole tools, each of which is equipped with a complex of measuring sensors and transmitting information via a wireline to the surface where a ground panel is installed that decodes the information and transmits it via communication channels (US Pat. RF No. 2244102). The disadvantage of this method is the individuality of each well, that is, the installation of a complete set of downhole and ground equipment on one well, in addition, the limited measuring means.

There is a method of controlling downhole parameters in high conductivity shielding formations, including measuring downhole parameters using a downhole telemetry system and transmitting them to an antenna installed below the high conductivity shielding layer and connected to ground receiving and processing equipment, due to the fact that said antenna is installed in an additional well filled with drilling fluid (US Pat. RF No. 2243377). To implement this method, a device for controlling downhole parameters in high conductivity shielding formations is used, comprising a downhole tool with measuring primary transducers, a transmitter, a power source, an electric splitter that acts as a dipole formed as a result of the electrical separation of the drill string, and an antenna mounted below high conductivity shielding layer and connected to ground receiving and processing equipment.

Known telemetry system, comprising a housing, a power supply, measuring and transmitting modules and an electrical splitter in the form of a separate sub (US Pat. RF №2105880, 2174694). A communication channel for transmitting deep parameters to the day surface is electromagnetic waves emitted by a telemetry system over rock. The system additionally contains at least two electrical dividers installed in the production casing, and a sleeve between the housing of the telemetry system and the separator to provide electrical communication with the upper part of the production string when lowering the housing of the telemetry system to the lower separator. However, this telemetry system does not allow exploring the production well, since the production string shields the propagation of electromagnetic waves through the rock.

The method according to RF patent No. 2174694 allows you to quickly obtain information on the surface and, in contrast to the method according to RF patent No. 224102, in particular, does not use a wireline cable, the use of which is difficult in wells using electric pumps. A common disadvantage of the known methods is the mandatory use of an electrical splitter in the production casing, which complicates the well construction process. In addition, this method is not applicable in the well stock with a production string that does not have an electrical separator.

Known methods for electromagnetic research of rocks behind the casing (US Pat. RF No. 2316026, No. 2342527), using electromagnetic waves to probe the near-wellbore space up to the neighboring well for measuring purposes and, possibly, to transmit information. A significant drawback of these methods is the high power consumption, as a result of the use of a logging cable. The use of the latter is undesirable in injection and production wells due to the rapid corrosion process and the complexity of the fixing process when installing pumping equipment.

A known method of electric cased hole logging, in which a probe is made in the form of two current electrodes located on opposite sides of at least three measuring electrodes spatially spaced without observing equidistance, providing for the electrical connection of production casing of two wells (RF patent No. 2302019), but its use is limited to wells that are not involved in the hydrocarbon production process.

The closest way to the claimed technical solution is the method of operating the well, including wellhead and bottomhole equipment, perforation and development, lowering the downhole tool into the production string, hydrodynamic and geophysical studies are performed with the downhole tool for measuring and transmitting hydrodynamic and geophysical parameters recorded in the electrical separator and carrying out hydrodynamic and geophysical studies with the transfer of information to the surface through exploitation the casing string with an electric separator that acts as a borehole dipole, the upper and lower sections of the production string before and after the electric separator are measuring electrodes for electric logging of the near-wellbore space, and the electric separator is a current electrode, and when several electric separators are installed in the calculated places of the production string change the characteristics of the sounding electric field near the borehole space, the length of the itelnyh electrodes shunting electric separator (Pat. RF №2196894).

The aim of this invention is the simplicity of the method of obtaining hydrodynamic and geophysical information for each object in any wells with minimal information errors.

This goal is achieved through the use of a method of operating wells, including installing ground-based receiving and producing equipment at the wellhead, perforating and developing wells, installing an electric separator, launching downhole measuring equipment with installed measuring electrodes in production casing, hydrodynamic and geophysical studies, transmitting information to the surface through a borehole dipole. The number of production casing is selected by at least two interconnected by an electrical conductor, while the production casing of wells with production equipment is connected to at least one production casing of the well, which allows you to install a wireline having downhole measuring equipment that has contact with the ground receiving equipment, function the borehole dipole perform the measuring electrode and the body of the borehole measuring equipment connected to the column, with In this case, an electric separator is installed on the downhole measuring equipment, and the measuring electrode has stable electrical contact with formation water.

In addition, the electrical conductor is equipped with a filtering device that transmits signals lying in the information frequency band.

When using the proposed method, the goal is achieved due to:

- the method of transmission from one well to another and / or vice versa or to a third (see figure 1),

- phase separation of the fluid in the analytical module of the downhole equipment,

- periodic measurement of the phase content in the analytical module of the downhole equipment,

- periodically updating a portion of the fluid in the analytical module of the downhole equipment,

- electrical connection of all production casing participating in the observation of wells.

Currently, existing borehole telemetry systems with an electric separator suggest the formation of an electromagnetic field. In view of the different nature of conductivity in metals and electrolytes, in particular drilling mud or produced water, the formation of an electromagnetic field in an electrolyte is associated with high energy costs and ultra-sensitive equipment, for example, RF patent No. 23535888. Under the preferred condition of abandoning the wireline cable and working in standalone mode, a new method of information transfer is required that has minimal losses. The authors see it in the transmission of reservoir fluid.

The experiments with a source amplitude of about 15 V at a current of 15 mA and a depth of 1 meter showed approximately linear attenuation of the signal at distances of 60, 200 and 400 meters. To check for spurious communication channels, the receiver and / or transmitter were removed from the formation water, and the transmitter was turned off electrically.

When using a receiver with a sensitivity of 1 μV, the range can reach up to several kilometers in produced water without the use of relaying, which allows monitoring a large number of wells.

The essence of the method is illustrated in figure 1, which shows a conventional image of three wells from above and equivalent electrical resistances, where 1 - production casing of existing wells, 2 - production casing of an inactive well, 3 - electrical conductors, 4 - measuring electrodes of downhole equipment.

Production casing wells 1 and 2 are connected by electrical conductors 3 to equalize the potentials. The equipment shells in the wells are electrically and mechanically connected to production casing. In one of the active wells, a potential difference is created between the measuring electrode 4 and the production casing of the active well 1. Due to the electrical connection of the production casing 1 and 2, a potential difference is created between the measuring electrode 4 located in the production casing of the active well 1 and other production casing. Possessing ionic conductivity, the produced water redistributes the potentials inside the other production casing, which fixes the measuring electrode 4, placed in these production casing and having a high input resistance Rrx.

Figure 2 shows a system of three wells, where 1 - production casing of existing wells, 2 - production casing of an idle well, 3 - electrical conductors, 4 - measuring electrodes, 5 - pumping equipment, 6 - downhole measuring equipment, ground receiving equipment, consisting of 7 - matching module and 8 - communication module, 9 - wireline cable, 10 - electrical splitter, 11 - protective cover.

The invention is as follows.

Operating wells are selected to monitor the production process. Near these wells, inactive or existing wells are selected that allow to install a logging cable, by the number less than the existing ones that do not allow to connect a logging cable to the downhole measuring equipment 6. In the production casing of the operating wells 1, downhole measuring equipment 6 is installed near the operating intervals, then the pumping pump is lowered equipment 5. Into the production casing of the idle well 2 lower the downhole measuring equipment 6 connected to the ground at using the logging cable 9 in an amount determined by the number of working intervals. The ground receiving equipment includes a matching module 7, which is connected to a communication module 8 having access to information networks or other communication lines. The selected active and inactive wells are interconnected by electrical conductors 3. Over time, the field monitoring coverage network can be expanded by installing downhole measuring equipment 6 in the active wells and electrically connecting the production casing with an electrical conductor 3 to the production casing of the monitored wells.

The experimental dependence of the received signal level on the distance in a system of two wells is shown in Fig. 3 — curve 1 and theoretical curve 2 for the case of an electromagnetic communication channel.

In the process of hydrocarbon production, information on the hydrodynamic parameters of the formation, in particular the degree of watering, is interesting. To transmit information downhole measuring equipment 6, a prerequisite is the contact of the measuring electrode 4 with formation water. Therefore, in the process of functioning, the device separates the phases of the reservoir fluid in the final volume, where, due to hydrostatic forces, light fractions are separated from heavy fractions. This allows you to measure the content of water and / or hydrocarbons in the place of installation of the device and to ensure uninterrupted operation of the device.

The control of the content of the separated phases occurs in transverse sections along the axis of the final volume, limited by the body of the downhole tool. The measurement process is accompanied by a natural and / or forced updating of a portion of the fluid passing by the device, associated with the rate of change of physical and chemical measurements performed by the device.

The electrical connection by electric conductors of 3 production casing of wells 1 and 2 involved in monitoring makes it possible not only to obtain hydrodynamic and geophysical information, but also to perform cross-hole measurements, examining in detail the characteristics of the received signal. Downhole measuring equipment has individual numbers indicated in the information package to separate information data from operational facilities. The use of error-correcting coding additionally minimizes information errors. In order to ensure the viability of the system, various options for transmitting information are possible, including, upon request, from downhole measuring equipment 6 connected via a wireline 9 to ground receiving equipment, periodic transmission from downhole measuring equipment 6 that does not have direct contact with ground receiving equipment at separated frequencies using relay request and / or response from a remote well or without it, etc.

In this regard, the power supply circuits of mining equipment, including protective grounding lines, can create different potentials between production cores, the electrical conductor can be equipped with a filtering device that transmits signals lying in the informative frequency band. For other signals of natural and industrial origin, the electrical conductor will be an electrical break, i.e. will not be a conductor.

Claims (2)

1. A method of operating a well, including installing ground-based receiving and producing equipment at the wellhead, perforating and developing wells, installing an electric separator, launching downhole measuring equipment with installed measuring electrodes in production cores, hydrodynamic and geophysical surveys, transmitting information to the surface via a borehole dipole, characterized in that the number of production casing strings is selected from at least two electrically interconnected m conductor, while the production casing of wells with production equipment is connected to at least one production casing of the well, which allows you to install a logging cable having downhole measuring equipment that is in contact with ground-based receiving equipment, the borehole dipole performs the function of the measuring electrode and the casing of downhole measuring equipment, connected to the column, while the electrical separator is installed on the downhole measuring equipment, and measure ny electrode has a stable electrical contact with the formation water. 2. The method of operating the well according to claim 1, characterized in that the electrical conductor is equipped with a filtering device that transmits signals lying in the information frequency band.

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