RU2495458C2 - Nuclear-magnetic logging device - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: disclosed is a nuclear-magnetic logging device which consists of at least one long magnet which is magnetised perpendicular to its longitudinal axis, and a radio-frequency coil for creating a field perpendicular to the field of the magnet, a radio pulse generator, a nuclear-magnetic resonance signal receiver and a matching device, the first input of which is connected to the beginning of the radio-frequency coil, the end of which is connected to the common point of the matching device, the second input of which is connected to the output of the radio pulse generator, and the output of the matching device is connected to the input of the nuclear-magnetic resonance signal receiver. The magnet is made from conducting rare-earth material SmCo in form of a long cylinder which is magnetised perpendicular to its longitudinal axis and the wide side surface. The radio-frequency coil is wound on a cylinder, the diameter of which is not less than the diameter of the cross-section of the magnet located inside the cylinder. Windings of the coil lie in planes parallel to the long axis of the magnet and perpendicular to its poles in symmetrical sectors lying opposite the poles of the magnet. A screening device is placed on top of the radio-frequency coil.

EFFECT: high sensitivity and depth of investigation during nuclear-magnetic logging with probes of small diameter.

6 cl, 2 dwg

Description

The invention relates to geophysical methods for researching wells, in particular to nuclear magnetic logging (NMR), used to study oil and gas wells.

A device for nuclear magnetic logging (US patent No. US 4710713, IPC G01N 24/00; G01N 24/08; G01R 33/44; G01V 3/28; G01V 3/32; H01F 7/20, publ. 01.12.1987) consisting of a circular cylindrical magnet made of ferrite and magnetized perpendicular to its long axis, and a radio frequency coil wound directly on the magnet, the coil turns lying mainly in the plane passing through the axis of the magnet and in the direction of its magnetization, a radio pulse generator, a signal receiver nuclear magnetic resonance and matching device, at the first input to torogo connected top RF coil, the end of which is connected to the common point of the matching device, to the second input of which is connected to the output radio pulse generator, and an output matching network connected to the input of the receiver nuclear magnetic resonance signals.

The disadvantage is that with a decrease in the diameter of the probe, for example to 114 mm, the sensitivity of the probe and the radius of the study area are reduced, which allows working only in small diameter wells. This disadvantage is due to the fact that the device uses a ferrite non-conductive magnet of round cylindrical shape, and the radio frequency coil is wound directly on the surface of the magnet.

Closest to the proposed invention is a device for nuclear magnetic logging (RF patent No. 2181901, IPC G01V 3/32, G01R 33/20, publ. 04/27/2002), containing at least one elongated magnet magnetized perpendicular to its longitudinal axis and at least one radio frequency coil, while the turns of the coil lie in planes parallel to the longitudinal axis of the magnet and the direction of its magnetization, matching device, a radio pulse generator and a receiver of signals of nuclear magnetic resonance, moreover, the radio frequency coil is connected it is connected to the first input of the matching device, the pulse generator is connected to the second input, and the output of the matching device is connected to the input of the receiver of nuclear magnetic resonance signals, the magnet is made of conductive rare-earth material (in this case, Nd-Fe-B) in the form of an elongated parallelepiped, magnetized perpendicular to its wide lateral surface, the width of the magnet not less than two times its narrow side, and the radio frequency coil is wound on a cylindrical frame, the diameter of which is not less than its diagonal cross-section of the magnet, inside the cylindrical shell, wherein the coil windings are arranged in symmetrical sectors which are opposite the broad side surface of the magnet, and the magnet is provided with a device compensating the RF field in the magnet.

The disadvantage of this device is that the magnets of the alloy Nd-Fe-B have poor stability at high temperatures and low corrosion resistance. The maximum working temperature of such alloys does not exceed 150-170 degrees. In the conditions of high bottomhole temperatures in the wells, research becomes impossible, since the strength of the static magnetic field decreases sharply. At the same time, at the same resonant frequency, the depth drops sharply, or at the same depth, the resonance frequency decreases, and, as a result, the sensitivity of the device decreases.

A common drawback of the above devices with a cylindrical layer for acquiring nuclear magnetic resonance (NMR) signals is the obligatory centering in the well and, as a result, the strong influence of the conductivity of the flushing fluid (or drilling fluid). When the resistance of the drilling fluid (or flushing fluid) is of the order of 0.05 Ohm * m or less, additional measures are required to eliminate such an effect of shunting the radio frequency antenna by the surrounding fluid.

The technical result of the invention is to increase the sensitivity and depth of research in nuclear magnetic logging with small diameter probes, as well as eliminating the negative effect of the conductivity (resistance) of the flushing fluid (drilling fluid).

The technical result is achieved in that in a nuclear magnetic logging device, consisting of at least one long magnet magnetized perpendicular to its longitudinal axis, and a radio frequency coil to create a field perpendicular to the magnet field, a radio pulse generator, a receiver of nuclear magnetic resonance signals and a matching device, the first input of which is connected to the beginning of the RF coil, the end of which is connected to a common point of the matching device, to the second input of which the output pulse generator, and the output of the matching device is connected to the input of the nuclear magnetic resonance signal receiver, the new one is that the magnet is made of a conductive rare-earth material SmCo in the form of a long cylinder magnetized perpendicular to its longitudinal axis and side surface, the radio frequency coil is wound on the cylinder, diameter which is not less than the diameter of the cross section of the magnet inside the cylinder, and the turns of the coil lie in planes parallel to the long axis of the magnet and perpendicular its poles in symmetrical sectors which are opposite the magnetic poles, and over the radio frequency coil is disposed a screening device.

On top of the shielding device is the casing of a nuclear magnetic logging probe.

The diameter of the radio frequency coil is as close as possible to the diameter of the protective casing.

The shielding device is a solenoidal coil, the turns of which are cut from one side and do not touch each other, and on the other hand are connected together by a conductor, which, in turn, is connected to a common point by ground.

The distance between adjacent turns of the shielding device does not exceed 3 cm.

A compensating device in the form of a short-circuited coil of copper is wound around the magnet.

New in the design of the nuclear magnetic logging device is that the magnet is made of a conductive rare-earth material SmCo in the form of a long cylinder magnetized perpendicular to its longitudinal axis, and the radio frequency coil is wound on a cylinder whose diameter is not less than the diagonal cross-section of the magnet inside the cylinder, moreover, the turns of the coil lie in planes parallel to the long axis of the magnet in symmetrical sectors opposite its poles. The magnet material allows operation in high ambient temperatures (up to 200 ° C). The magnetic field strength at the working distance (of the order of 170-180 mm) is greater than that of the same magnet made of Nd-Fe-B material, which makes it possible to receive signals in the region that lies farther deep into the reservoir with the same signal-to-noise ratio (large the depth of the device), or at the same depth, have a greater signal-to-noise ratio (high sensitivity of the device).

The diameter of the radio frequency coil is as close as possible to the protective casing in order to increase its sensitivity. An increase in the diameter of the radio frequency coil leads to a negative effect of the surrounding flushing fluid (drilling fluid) on the probe, or rather the resistance of this fluid (or the conductivity of the flushing fluid), since they are very close. A conductive drilling fluid shunts the quality factor of the RF coil, thereby reducing its sensitivity. The shielding device solves the problem of maintaining the quality factor of the coil in a wide range of conductivity of the drilling fluid.

In addition, it is new that the shielding device is a solenoidal coil, the turns of which are cut from one side and do not touch each other, and on the other hand are connected together by a conductor, which, in turn, is connected to a common point by ground. The distance between adjacent turns of the shielding device does not exceed 3 cm.

The device is characterized by figure 1 and figure 2.

Figure 1 presents a General diagram of a device for nuclear magnetic logging.

Figure 2 presents the probe of nuclear magnetic logging.

The nuclear magnetic logging device includes a nuclear magnetic logging probe 1, a matching device 2, a radio pulse generator 3 and a receiver 4. An output of a radio pulse generator 3 is connected to the second input of the matching device 2, and the output of the matching device is connected to the input of the receiver 4.

A nuclear magnetic logging probe 1 consists of a long cylindrical magnet 5 magnetized perpendicular to its longitudinal axis. A compensation device 6 is wound around the magnet 5 in the form of a short-circuited coil of copper. The magnet 5 is inserted into the cylindrical frame 7, on which the winding of the radio frequency coil 8 is wound. The coil winding is located in 120 ° symmetrical sectors opposite the poles of magnet 5. A shielding device 9 is located on the radio frequency coil 8, the edge of which is a bus to which are soldered all turns of the solenoidal coil, located in the window of the RF coil 8 and connected to a common point of the matching device 2. On top of the shielding device 9 is a casing 10 of a nuclear magnetic logging probe 1 for I protect against external influences.

The nuclear magnetic logging device operates as follows.

Magnet 5 generates a plane-parallel static magnetic field of magnitude H ₀ at a distance r from the axis of the magnet. The magnitude of the field H _{0 is} constant over the entire circle of radius r. The direction of this field is different at different points in the circle. The radio frequency coil 8, wound on a cylindrical frame 7, using a matching device 2 is connected to the generator of radio pulses 3 and generates a plane-parallel radio frequency field H ₁ , which at a radius r also has a constant value. The direction of the radio frequency field H ₁ at each point of the circle of radius r is perpendicular to the field H ₀ . When the frequency of the radio frequency field H ₁ coincides with the frequency of the precession of hydrogen nuclei in the field H ₀ in the study zone 11, the phenomenon of nuclear magnetic resonance occurs. After that, the matching device 2 connects the radio frequency coil 8 to the receiver 4 and thereby the signals of nuclear magnetic resonance are recorded. A short-circuited turn 6 compensates for the effect of the magnet on the RF coil 8. The shielding device 9 removes the dependence of the Q factor of the RF coil on the conductivity (resistance) of the drilling fluid (flushing fluid), which covers the probe 1.

Claims (5)

1. A nuclear magnetic logging device, consisting of at least one long magnet magnetized perpendicular to its longitudinal axis, and a radio frequency coil to create a field perpendicular to the magnet field, a radio pulse generator, a receiver of nuclear magnetic resonance signals and a matching device, the first input of which the beginning of the RF coil is connected, the end of which is connected to the common point of the matching device, the second input of which is connected to the output of the radio pulse generator, and the output its device is connected to the input of the receiver of nuclear magnetic resonance signals, characterized in that the magnet is made of a conductive rare-earth material SmCo in the form of a long cylinder magnetized perpendicular to its longitudinal axis, a radio frequency coil is wound on a cylinder whose diameter is not less than the diameter of the cross section of the magnet located inside the cylinder, and the coil turns lie in planes parallel to the long axis of the magnet and perpendicular to its poles in symmetrical sectors opposite the poles magnet, and on top of the RF coil there is a solenoidal coil, the turns of which are cut from one side and do not touch each other, and on the other hand are connected together by a conductor, which, in turn, is connected to a common point by ground. 2. The device according to claim 1, characterized in that on top of the shielding device is a casing of a nuclear magnetic logging probe. 3. The device according to claim 1, characterized in that the diameter of the radio frequency coil is as close as possible to the diameter of the casing. 4. The device according to claim 1, characterized in that the distance between adjacent turns of the solenoidal coil does not exceed 3 cm 5. The device according to claim 1, characterized in that a compensating device in the form of a short-circuited coil of copper is wound on a magnet.

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