RU167730U1 - Device for monitoring the quality of casing cementing in gas wells - Google Patents

Abstract

The proposed utility model relates to the field of geophysical research of oil and gas wells by the acoustic method and is intended to control the quality of casing cementing. The objective of the proposed utility model is to increase the reliability of the device during the study of gas wells. The device contains a device body with pressure springs, acoustic transducers placed in containers on hold-down springs having the ability to press containers to the wall of the well, with each con the tuner with an acoustic transducer is sealed and installed on one end of each of two pairs of brackets spaced along the length of the housing, the other end of each of which is connected to an electro-hydraulic drive mechanism that is located in the housing and is controlled from the surface, and each acoustic transducer is made in the form of -shaped ferromagnetic core with a winding wound around it, forming a solenoid facing the borehole wall with the open side of the U-shaped ferromagnetic core, creating when a sealed container contacts the well wall, a closed magnetic circuit. The winding of each solenoid is connected via a switch to a current pulse generator and an amplifier of the received current pulses in the electronic circuit of the device, which contains a control unit for the electro-hydraulic drive mechanisms of the brackets and a synchronization unit for the operation of the current pulse generator.

Description

The proposed utility model relates to the field of geophysical exploration of oil and gas wells by the acoustic method and is intended to control the quality of casing cementing.

A known method of acoustic logging of wells and a device using a pipe as an acoustic transmitter (US Pat. US No. 3752257, priority 08/14/1973).

The known device is a rod with high conductivity, on which a winding is wound, connected to a high voltage source. The device is placed in a metal container-pipe, lowered into the well on the cable. Voltage pulses passing through the coil create a magnetic field that deforms the pipe and creates an acoustic transmitter in it. Acoustic pulses pass through the rocks and are received by acoustic receivers located near the transmitter. From the measured sound velocities in the strata, rock characteristics are calculated.

The known tool is intended for the study of wells filled with fluid, which is a necessary condition for the propagation of "refracted" waves of acoustic logging.

In the case of researching gas wells, they have to be filled with liquid (water) for the duration of the research, which can have a negative effect on gas-saturated formations in operation and significantly reduce their productivity, which is often difficult to restore to the initial level.

Known acoustic logging device designed for research in wells filled with gas, gas-saturated liquid and foams (Yu.A. Gutorov, AM Gilmanova. Modern geophysical instrumentation complexes based on the acoustic method for researching oil and gas wells. Ufa, UGNTU. 2013, p. 78-80).

The device contains acoustic transducers (emitters and receivers) located on the spring loaded clamping levers, with the help of which they are pressed against the borehole wall or to the casing string (OK). Acoustic transducers themselves have a toroidal shape, are made of magnetostrictive material with a winding deposited on it and are placed in an oil-filled container, which also has a toroidal shape, which contacts its surface with the borehole wall (OK).

Acoustic vibrations from the toroidal core-emitter enter the oil filling the container, and then through the area of its contact with the borehole wall they penetrate the rock in the form of “refracted” longitudinal waves and achieve a receiving transducer similar in design and are recorded by the electronic circuit of the borehole probe.

Such a design of clamping acoustic transducers allows for acoustic logging in wells filled with any, including gas contaminated, and clean gas.

A disadvantage of the known design is the low reliability of acoustic transducers associated with the rapid wear of an oil-filled elastic shell, inside of which there is a toroidal core with an excitation-receiving winding, as well as the instability of the acoustic characteristics due to the gradual penetration of gas due to the high permeability of the elastic shell into the oil-filled container during the process finding a downhole probe in a gas-filled well.

The objective of the proposed utility model is to increase the reliability of the device during the study of gas wells.

The proposed utility model also solves the technical problem of exploring gas wells without filling with water, which eliminates the decrease in their productivity.

This problem is solved by the fact that in the device for monitoring the quality of cementing of casing strings in gas wells, containing the device body with pressure spring levers (springs), acoustic transducers placed in containers on pressure springs, which have the ability to press containers to the wall of the well, unlike known, each container with an acoustic transducer is sealed and installed on one end of each of two pairs of brackets spaced along the length of the housing, the other end of each one of which is connected to an electro-hydraulic drive mechanism, which is located in the housing and controlled from the surface, and each acoustic transducer is made in the form of a U-shaped ferromagnetic core with a winding wound on it, forming a solenoid facing the borehole wall with the open side of the U-shaped ferromagnetic core creating a closed magnetic circuit upon contact of the sealed container with the wall of the well, while the winding of each solenoid is connected through a switch to a current generator O and the amplifier pulses received current pulses in the electronic circuit device, which comprises a control unit for electro-hydraulic drive mechanisms and brackets of the generator current pulse synchronization unit. The sealed containers are filled with a dielectric, insulating composition having abrasion-resistant properties, for example, an epoxy compound.

In FIG. 1 is a schematic diagram of a device.

In FIG. 2 shows the electronic circuit of the device.

A device comprising a housing 1, equipped with two pairs of pressure springs 2 and 3, is lowered into a well with a casing 4 and a cement ring 5, in which defects of volume 6 and contact 7 are formed, which can serve as channels 8 for annular gas filtration from the gas reservoir 9 opened by the interval of perforation 10 (Fig. 1).

On the housing 1 there are two pairs of brackets spaced along the length of the housing 1. In the first pair of brackets 11, one end of each bracket is connected to an electro-hydraulic drive mechanism 12, which is located in the housing 1 and is controlled from the surface, and the free ends of the brackets 11 are equipped with sealed containers 13 containing acoustic transducers made in the form of a ferromagnetic U-shaped core 14 s wound on it with a winding 15. The sealed containers are filled with a dielectric, insulating composition having abrasion-resistant properties, for example, an epoxy compound.

U-shaped cores 14 with a winding 15 wound thereon are placed in sealed containers 13 mounted on the first pair of pressure springs 2, pressed by the first pair of pressure springs 2 to the casing wall 4 with side 16 overlapping the open part 17 of the U-shaped core 14, forming a closed magnetic circuit in contact with the wall of the casing 4. The first pair of brackets 11 is driven by an electro-hydraulic drive mechanism 12 controlled by a control unit 18 located in the sealed compartment 19 of the housing 1. In the compartment 20 of the housing 1 there is an electronic circuit with a device synchronization unit 21 having two-way electrical communication with the control unit 18. Output unit 21 for synchronizing the operation of the device is connected to a current pulse generator 22, the output of which is connected to a switch 23 having two-way electrical communication with block 21 for synchronizing the operation of the device. One output of the switch 23 is connected to an amplifier of the received current pulses 24, which is connected by its output to the synchronization unit 21. Another output of the switch 23 is connected to the winding 15 of the U-shaped core 14 (Fig. 2).

At some distance from the first pair of brackets 11 with solenoids on the housing 1 is located (similar to the first pair) a second pair of brackets 25 provided with sealed containers 26 containing acoustic transducers made in the form of a ferromagnetic U-shaped core 27 with a winding 28 wound on it. shaped cores 27 with a winding 28 wound thereon are placed in sealed containers 26 secured to a second pair of pressure springs 3, pressed by a second pair of pressure springs 3 to the casing wall 4.

The second pair of brackets 25 is driven by an electro-hydraulic drive mechanism 29 controlled by a single control unit 18. In this case, the coil 28 is connected to the switch 23 (Fig. 2).

The device operates as follows.

A device on a geophysical cable is lowered into a well with a metal (steel) casing 4 and cement ring 5 (not shown in FIG. 1). The clamping springs 2 and 3 of the housing 1 are in a folded (pressed) state due to the fact that the brackets 11 and 25 connected to the airtight containers 13 and 26 mounted on the clamping springs 2 and 3 are in the folded state and are kept from opening by electro-hydraulic drive mechanisms 12 and 29, controlled by a control unit 18 located in the sealed compartment 19 of the housing 1 and connected via a geophysical cable to the surface. At the same time, sealed containers 13 and 26 fixed on the clamping springs 2 and 3 with the solenoids 14 and 27 located in them in the form of a ferromagnetic U-shaped core with a winding wound on it are removed from the wall of the casing 4 and have no contact with it.

When the device reaches the interval of interest, for example, where defects of volume 6 and type 7 are formed, a command is sent to the control unit 18 of the electronic circuit of the device (Fig. 2) from the surface via a geophysical cable to actuate the electro-hydraulic drive mechanisms 12 and 29 that open the brackets 11 and 25, while the pressure springs 2 and 3 due to the elasticity have the ability to pressurized containers 13 and 26 with the solenoids 14 and 27 located in them to the wall of the casing 4, while providing sliding contact between them and OK 4.

Then, the control unit 18 receives a command to start the unit 21 for synchronizing the operation of the device, the current pulse generator 22 and the amplifier of the received current pulses 24.

The current pulses from the generator 22, passing through the winding 15, excite in the ferromagnetic U-shaped core 14 a short-term field of magnetic induction, which is closed through the local section of the casing 4 (since the sealed containers 13 side 16 with the solenoids 14 located in them are pressed against the OK wall) , creates in this section a strong attractive-repulsive mechanical deformation, which causes an elastic impulse in the OK wall, propagating from the place of its excitation in both directions along the OK 4 steel wall with a speed of more 5000 m / s and reaches the location of the second pair of brackets 25 with sealed containers 26 with the solenoids 27 in them in the form of a ferromagnetic U-shaped core with a winding 28 wound on it. In this case, the elastic impulse, due to a change in the magnetic permeability of the gap between the OK wall and a ferromagnetic U-shaped core 27, induces self-induction EMF in its winding 28 in the form of a current pulse, the amplitude of which depends on the magnitude of the amplitude of the elastic pulse that reached it, which in turn depends on the hard the contact of the cement ring 5 with OK 4 and the type of cement stone defect located behind it: volume 6 or contact 7. The current pulse received by the winding 28 is transmitted through the switch 23 to the amplifier of the received current pulses 24 and then transmitted to the device synchronization block 21 with the subsequent transmission to the control unit 18 of the electronic circuit of the device and then to the surface by cable (in FIG. 1 not shown).

For a more reliable assessment of the state of the contacts of the cement ring 5 with OK 4 in a gas well in the electronic circuit of the device, the "reverse" mode is provided when the control unit 18 is switched from the surface using a switch 23 having two-way electrical communication with the device synchronization block 21, the output of the current pulse generator 22 to supply current pulses to the second pair of solenoids 27, and the solenoids 14 of the first pair, installed in sealed containers 13, are connected to the input of the amplifier of the received current pulses 24.

The obtained measurement results in the OK interval intended for the study in each of the two modes are transmitted to the surface through the operation control unit 18 of the electronic circuit of the device, where they are compared with each other to obtain a generalized diagram that more reliably characterizes the contact state of the cement ring 5 with OK 4.

The design of the inventive device allows the use of steel OK 4 at the same time as a source and conductor (waveguide) of elastic vibrations in the cement ring surrounding it, and then register the received elastic vibrations of OK 4 at some distance from the place of excitation, the intensity of which varies depending on the degree of damping of OK 4 a cement ring behind it at different densities of contact between them, regardless of the type of medium filling the internal volume of the well, including completely gas.

The solution to the technical problem of researching gas wells without filling them with water using the claimed device is provided by a special design of acoustic transducers for exciting and receiving “direct” acoustic waves in the OK 4 column and pressure springs, which ensure their contact with the OK 4 wall in sliding mode, providing the necessary the density of their contact with the OK 4 wall, which significantly distinguishes the proposed solution from the known designs of acoustic transducers operating on “refracted” a usticheskih waves requiring filling wells liquid or transmitting elastic vibrations into the casing through the immersion liquid filling the container with the magnetostrictive transducers.

Claims (2)

1. A device for monitoring the quality of cementing of casing strings in gas wells, comprising a device casing with pressure springs, acoustic transducers placed in containers on pressure springs, which are able to press containers to the wall of the well, characterized in that each container with an acoustic transducer is sealed and mounted on one end of each of two pairs of brackets spaced along the length of the housing, the other end of each of which is connected to an electro-hydraulic drive unit anism, which is located in the casing and controlled from the surface, and each acoustic transducer is made in the form of a U-shaped ferromagnetic core with a winding wound around it, forming a solenoid facing the well wall with the open side of the U-shaped ferromagnetic core, creating a sealed container with the borehole wall is a closed magnetic circuit, while the winding of each solenoid is connected through a switch to a current pulse generator and an amplifier of the received current pulses in the electric an electronic device circuit that contains a control unit for the electro-hydraulic drive mechanisms of the brackets and a synchronization unit for the operation of the current pulse generator. 2. A device for monitoring the quality of cementing of casing strings in gas wells according to claim 1, characterized in that said sealed containers are filled with a dielectric insulating composition having abrasion-resistant properties.

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