RU2764609C1 - Acoustic moisture meter for inclined and horizontal wells - Google Patents

Abstract

FIELD: oil industry.SUBSTANCE: invention relates to equipment for geophysical and hydrodynamic studies in the oil industry in the study of operating wells. The device includes a cylindrical body, which is divided along the longitudinal axis into n equal sectors, electrically isolated from each other by radial partitions. The housing is equipped with 2n acoustic transducers installed in pairs inside each of the segments at opposite ends of the housing opposite each other and each of which is connected to an electronic control and processing circuit.EFFECT: accuracy and reliability of measurements is increased.1 cl, 2 dwg

Description

The invention relates to the field of geophysics, in particular to equipment for geophysical and hydrodynamic studies of wells in the oil industry in the study of existing wells.

A well-known moisture meter is made in the form of a flow condenser, one plate of which is a central insulated rod, and the other is the body of the measuring channel, where the investigated flow of the well fluid is directed with the help of a packer. (Gabdullin T.G. "Operational study of wells", M.: Nedra, 1981, pp. 111-116).

The device is simple in design. The main disadvantage of this moisture meter is the difficulty of providing absolute packer and the violation of the dynamics of the flow of a multicomponent liquid (oil, gas, water).

Known complex downhole tool "AGAT-K9" (scientific and technical bulletin AIS "Karotazhnik", Tver, 2005, No. 10-11, p. 122-125), lowered into the well on a logging cable, consisting of several modules, basic the module of which contains a downhole fluid composition sensor.

A device for monitoring the development and operation of a gas well (RF, 2230903 E21B 47/00) is known, which contains a cylindrical body, on top of which there is a docking unit with a logging cable. Sensors of downhole fluid parameters, as well as a downhole fluid moisture sensor and electronic boards are installed in the body itself, a centralizer is installed on the body, centering the device itself along the axis of the well.

The disadvantage of the known devices is the impossibility of detecting the degree of gravitational stratification of the well fluid in horizontal and highly inclined wells, due to the presence in these devices of only one moisture sensor located in the center of the device. depends on the density and composition of the well medium and introduces its own errors in the measured parameters.

The objective of the present invention is to improve the reliability and accuracy of determining the moisture content of the well fluid and ensure the operation of the device and inclined and horizontal wells.

The problem is solved in the following way.

In an acoustic moisture meter for inclined and horizontal wells, containing a hollow cylindrical body with an acoustic transducer connected to an electronic control and processing circuit, according to the invention, the cylindrical body along the longitudinal axis is divided into n equal sectors, electrically isolated from each other by radial partitions, and is equipped with 2n acoustic converters installed in pairs inside each of the sectors in opposite ends of the housing opposite each other and each connected with an electronic control and processing circuit.

Advantages compared to known devices:

- the presence of 2n acoustic transducers, installed in pairs inside each of the n-sectors in opposite ends of the body opposite each other and each connected to an electronic control and processing circuit, makes it possible to apply a compensation method for monitoring the moisture content parameter of the well fluid, based on measuring the propagation time of probing pulses in the well environment, regardless of their travel speeds. Since the propagation time of each of the probing pulses does not depend on the amplitude of the pulse itself, the measured compensation time parameter in this case will not depend on the complexity of the composition of the well medium (a mixture of oil, water or other solid and liquid impurities), which ensures the accuracy of the measured moisture parameter,

- the presence of radial partitions dividing the housing along the longitudinal axis into n-sectors, electrically isolated from each other, eliminates the mutual influence of the probing pulses of the transducers of one sector on the probing pulses of the transducers of neighboring sectors, which ensures the reliability and accuracy of the measured parameter (the travel time of the probing pulses between acoustic converters in each of the sectors),

- the presence in the design of 2n acoustic transducers, placed in pairs in each of the sectors, provides during the tripping operation the possibility of sounding the well area simultaneously in all radial directions of the body circumference, which increases the radius of effective impact on the studied area of the well by increasing the acoustic power of the device, i.e. makes it possible to use the proposed acoustic moisture meter in inclined and horizontal wells, since the implemented compensation method for controlling the moisture content parameter of the well fluid does not depend on the degree of inclination of the well.

In FIG. 1 shows a design variant of the proposed acoustic moisture meter. In FIG. 2 shows the interaction diagram of the acoustic transducer in the case.

The acoustic moisture meter of inclined and horizontal wells (hereinafter referred to as the device) contains a cylindrical body 1, divided along the longitudinal axis by insulating partitions 2 into equal sectors 3 along the circumference of the body 1. At the opposite ends of the body 1, inside each of the sectors 3, acoustic transducers 4 are installed - the first row and acoustic transducers 5 - the second row, the emitters of which are directed towards each other.

In the described design variant (Fig. 1) the body 1 of the device is divided into six sectors 3 (n=6). Twelve acoustic transducers are installed in sectors 3, respectively (2n=12) - six acoustic transducers 4 of the first row and six acoustic transducers 5 of the second row installed opposite them, each of which is electrically connected to an electronic control and processing circuit (not shown in the figure).

Thus, the device is a system of twelve acoustic transducers 4 and 5 of the first and second row, respectively (Fig. 2), located in pairs opposite each other in each of the sectors 3 at the ends along the circumference of the housing 1.

The operation of the device is carried out as follows.

In the process of tripping operation in the device in each of the sectors 3 acoustic transducer 4 of the first row sends a probing pulse to the acoustic transducer 5 of the second row. As soon as the pulse of the acoustic transducer 4 of the first row reaches the acoustic transducer 5 of the second row, the latter with a delay equal to the travel time of the pulse from the transducer 4 of the first row emits a counter probing pulse. Information about the travel time of each of the pulses of each pair is fed to the electronic processing and control circuit for comparison and the necessary calculations of the desired humidity parameter.

As a result, in the process of measuring the travel time of acoustic signals in each sector in the direction of movement of the device and in the opposite direction, a system of equations is formed:

(T ₁₁ +t _k ), (T ₁₂ +t _k ), (T ₁₃ +t _k ), (T ₁₄ +t _k ), (T ₁₅ +t _k ), (T ₁₆ +t _k ) - measured time run of the probing pulse in the direction of movement of the device,

(T ₂₁ -t _k ), (T ₂₂ -t _k ), (T ₂₃ -t _k ), (T ₂₄ -t _k ), (T ₂₅ -t _k ), (T ₂₆ -t _k ) - measured time run of the probing pulse against the direction of movement of the device, where:

T ₁₁ , T ₁₂ , T ₁₃ , T ₁₄ , T ₁₅ , T ₁₆ , is the travel time of the probing pulse from the transducers 4 of the first row to the corresponding transducers 5 in its sector in the second row;

t _k - time of passage of the tool during logging;

T ₂₁ , T ₂₂ , T ₂₃ , T ₂₄ , T ₂₅ , T ₂₆ , is the travel time of the probing pulse from the transducers 5 of the second row to the corresponding transducers 4 in the first row;

t _k - time of passage of the tool during logging. Then the liquid travel time in each sector 3 will be determined by the formula:

T _W1 \u003d {(T ₁₁ +t _k ) + (T ₂₁ -t _k )} / 2 \u003d (T ₁₁ + T ₂₁ ) / 2

T _W2 \u003d {(T ₁₂ +t _k ) + (T ₂₂ -t _k )} / 2 \u003d (T ₁₂ + T ₂₂ ) / 2

T _W3 \u003d {(T ₁₃ +t _k ) + (T ₂₃ -t _k )} / 2 \u003d (T ₁₃ + T ₂₃ ) / 2

T _W4 \u003d {(T ₁₄ +t _k ) + (T ₂₄ -t _k )} / 2 \u003d (T ₁₄ + T ₂₄ ) / 2

T _W5 \u003d {(T ₁₅ +t _k ) + (T ₂₅ -t _k )} / 2 \ _{u003d (T 15} + T ₂₅ ) / 2

T _W6 \u003d {(T ₁₆ + t _k ) + (T ₂₆ -t _k )} / 2 \u003d (T ₁₆ + T ₂₆ ) / 2

Since one cycle is recorded six values (number of sectors) T _x1, T _x2, T _{x3 x4} T T T _{zh6 J5,} probing pulses path speed respectively will be defined as:

V _{1 \u003d} S / T w1; V _{2 \u003d} S / T w2; V ₃ \u003d S / T _w3 ; V _{4 \u003d} S / T w4; V _{5 \u003d} S / T w5; V _{6 \u003d} S / T w6,

where S is the distance between acoustic transducers 4 and 5 (body ends).

It is known that the speed of sound in water is equal to V _in =1403 m/s, in oil V _n =1225 m/s, then by the ratio of the obtained values of V _in and measured V _i data in each sector, one can determine the oil humidity Q:

Q _i \u003d (V _i / V _in ) / 100,

where V _i is the measured speed of the acoustic pulse in each of the sectors 3 of the housing 1,

V _in - the speed of sound in water,

V _n - the speed of sound in oil.

Thus, the fixed travel time of the probing pulses is compensated for by the influence of the logging speed, which ensures an increase in the accuracy of determining the composition of the well fluid.

At the same time, since the measurement of the travel time of the sounding pulses is carried out by the transducers of each of the sectors simultaneously, the radius of the effective impact of the downhole acoustic transducer on the studied zone of the well increases due to the increase in the acoustic power of the device, which ensures the operation of the proposed device both in vertical and in inclined and horizontal wells .

The proposed design of an acoustic moisture meter for inclined and horizontal wells is simple and reliable; in technical implementation, it does not require the use of special materials and equipment.

Claims (1)

Acoustic moisture meter for inclined and horizontal wells, containing a hollow cylindrical body with an acoustic transducer connected to an electronic control and processing circuit, characterized in that the cylindrical body along the longitudinal axis is divided into n equal sectors, electrically isolated from each other by radial partitions, and is equipped with 2n acoustic transducers installed in pairs inside each of the segments in opposite ends of the housing opposite each other and each connected with an electronic control and processing circuit.

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