ES2927494B2 - Apparatus for measuring the magnetic susceptibility of mineral samples - Google Patents

Description

DESCRIPTION

Apparatus for measuring the magnetic susceptibility of mineral samples

Technical sector

The invention is part of the technical sector of electronic instrumentation, specifically, in the characterization of magnetic materials. The invention is related to a portable susceptometer based on permanent magnets for the characterization of magnetic minerals whose portability makes it of special interest in geophysics.

Background of the invention

The main magnetic susceptibility measurement systems used in the state of the art are explained below.

VSM (Vibrating-sample magnetometer)

The basic operating principle of a VSM is to measure the variation of magnetic flux in a region of uniform field when a sample is introduced into it. The principle of operation is described in S. Foner, "Versatile and Sensitive Vibrating-Sample Magnetometer," Rev. Sci. Instrum., vol. 30, no. 7, p. 548 557, 1959, https://doi.org/10.1063/1.1716679 and D. Jiles, Introduction to magnetism and magnetic materials, [Repr.]. London [etc.: : Chapman and Hall, 1994.

Through the use of electromagnets, a magnetic field is generated in the region in which the sample is introduced. The total B field in the region will be due to the field produced by the electromagnet plus that produced by the magnetized sample.

The area where the sample is located includes a set of measuring coils that, following Faraday's law, allow flux variations to be measured according to the electromotive force induced in their terminals.

The sample is made to vibrate so that it moves away from and towards the measurement secondaries. A flow variation appears in them due to the vibration of the sample magnetada. As the vibration frequency is known, by integrating the potential difference in the secondary terminals it is possible to obtain the magnetization of the sample.

To achieve uniformity in the measurement region, the pole pieces must be much larger than the sample to be measured, therefore the apparatus tends to be bulky and heavy while the samples must be much smaller than them.

On the other hand, since electromagnets are used to generate the field that magnetizes the sample, which require large currents for their operation, this device also has a large consumption and requires a powerful power supply system.

AGM (Alternating-gradient magnetometer)

The AGM is a variant of the VSM that allows sensitivities around 100 times greater than a conventional VSM of a similar size. The sample to be analyzed is fixed at the end of a rod attached to a cantilever that incorporates a piezoelectric.

The sample is magnetized by a DC field (whose amplitude can be varied) and simultaneously subjected to a small alternating field gradient. This alternating field exerts a force on the sample proportional to the field gradient and the magnetization of the sample, and as a consequence the sample vibrates. These vibrations cause a voltage in the piezoelectric that can be measured and allows the magnetization of the sample to be obtained. The principle of operation is described in the documents G. Asti and M. Solzi, “Alternating field gradient susceptometer,” J. Magn. Magn. mater., vol. 157-158, p. 559-560, 1996, https://doi.org/10.1016/0304-8853(95)01012-2 and P. J. Flanders, “An alternating-gradient magnetometer (invited),” J. Appl. Phys., vol. 63, no. 8, p. 3940-3945, 1988, https://doi.org/10.1063/1.340582.

Subjecting the sample to alternating fields with frequencies close to the resonance of the system, the voltage measured in the cantilever can be amplified. However, this also limits the size of the samples, since if they are too large they can vary considerably the resonance frequency of the system.

Once again, this system has a large consumption, a large size and a heavy weight because the fields are also generated by electromagnets.

SQUIDS (Superconducting quantum interference devices)

SQUIDS are the most accurate magnetic field measurement devices to date. These devices consist of a ring of superconductor with a small insulating layer known as a Josephson junction or weak junction. When the temperature is lowered until the ring becomes superconducting, the flux through the ring is quantized, and the Josephson junction allows the flux to vary in discrete steps. By winding a coil around the ring it is possible to measure the voltage induced in the coil due to quantized jumps in the flux value.

Although this device is the most accurate of those discussed, it also requires more sophisticated measurement conditions, mainly in terms of temperature, for superconductors to go into superconducting state. In addition, it also uses electromagnets to magnetize the samples, therefore, it is also not exempt from a high power, heavy and bulky power system.

VSM With permanent magnets

It is a more compact model than the conventional VSM where the field sources are replaced by two Halbach cylinders built with permanent magnets. The principle of operation is described in the document O. Cugat, R. Byrne, J. McCaulay, and J. ~M. ~D. Coey, “A compact vibrating-sample magnetometer with variable permanent magnet flux source,” Rev. Sci. Instrum., vol. 65, no. 11, p. 3570 3573, 1994, https://doi.org/10.1063/1.1144538.

The cylinders produce a uniform field inside them given by:

Where Br is the remanence of the magnets and R and r the ratio between the radii of both cylinders. The factor f responds to the non-idealities of the cylinder system.

Displacing the cylinder from the outside with respect to the inside, we obtain a field given by the vector sum of the fields due to both cylinders:

#0 = #1 #2

Making the magnetization of both cylinders the same, that is, B1 = B2, fields from 0 to ±2 B1 can be obtained.

Attempts have been made to implement versions based on the more compact and portable Halbach cylinders as in P. Stamenov and JMD Coey, “Vector vibrating-sample magnetometer with permanent magnet flux source,” J. Appl. Phys., vol. 99, no. 8, p. 08D912, 2006, https://doi.org/10.1063/E2170595 which leads to:

• Maximum sample sizes up to 100 mm3

• Field homogeneity in an area of 2x2 mm (with variations of less than 2%) and with fields up to 0.12 T.

• Resolution in the field variation of about 1 mT.

Hallbach-like assemblies are currently used as low-power, reliable, and portable magnetic field sources. These assemblies are hollow cylindrical structures made with permanent magnet arrays (HCPMA, hollow cyíindricaípermanente magnet array), in which the materials with which the cylinder is made can be alternated in order to improve its performance.

Recently articles have been published about possible improvements of this configuration:

• Using in the matrix segments with high energy product, very high coercivity magnets (up to approximately 2T) and soft iron to improve maximum field and uniformity as disclosed in the document X. Xu, D. Lu, X. Xu , Y. Yu, and M. Gu, “Optimizing the field distribution of a Halbach type permanent magnet cylinder using the soft iron and superhard magnet,” J. Magn. Magn. mater., vol. 445, p. 77-83, 2018, https://doi.org/10.1016/j.jmmm.2017.08.081.

• With an outer layer of high permeability material.

Explanation of the invention

As explained in the section on the state of the art, current magnetic susceptibility measuring devices, susceptometers, based on the use of electromagnets to achieve magnetization of the samples to be measured, require large power supplies due to its large consumption, which hinders its portability and limits the size of the samples.

The Hallbach cylinder-based susceptometer does not use electromagnets for the magnetization of the samples, thus reducing the consumption of the apparatus. However, it does limit the sample sizes to small samples marked by regions where the field is uniform.

The invention allows the magnetic characterization of minerals by means of a portable device that allows them to be carried out "in-situ". In order to allow a portable device, the apparatus object of the invention replaces the electromagnets of the usual susceptometers with an assembly based on permanent magnets and a magnetic circuit.

With all this, the present invention consists of a portable instrumentation system, which allows to measure the magnetic susceptibility of mineral samples in-situ. In addition, the samples may have a size greater than that which can be used in the apparatus of the state of the art.

The apparatus for measuring the magnetic susceptibility of mineral samples object of the invention comprises two U-shaped branches arranged symmetrically and facing each other according to a longitudinal direction of the apparatus, where each one of the U-shaped branches comprises:

- respective pieces of iron comprising a first and a second longitudinal end and configured to face the mineral sample at the first longitudinal end,

- respective permanent magnets located after the iron pieces according to the longitudinal direction of the apparatus that comprise a first and a second longitudinal end and that have their first longitudinal end facing the second longitudinal end of the pieces of iron, and

- a U-shaped piece of iron comprising a plate placed transversely and two projections facing the second longitudinal end of the permanent magnets.

The apparatus also comprises a sample holder located between the iron pieces of both U-shaped branches. The sample holder is configured to rotate around a longitudinal axis of the apparatus so that through said rotation it positions the samples longitudinally facing the iron pieces. .

The apparatus object of the invention allows:

• generating the field with which the samples are magnetized by means of permanent magnets, for example, NdFeB (neodymium magnet), and a soft iron magnetic circuit, which greatly reduces the consumption of the apparatus with respect to suceptometers based on electromagnets.

• Being a portable device that allows the characterization of samples in-situ.

• measure the magnetization of samples using an easily accessible rotating sample holder where samples move in and out of the measurement regions in circular motions.

The present invention refers to a susceptometer capable of measuring cylindrical-shaped samples up to 20mm in diameter x 20mm in height, or with arbitrary geometries as long as they are contained within the 20mm x 20mm cylindrical region. In this way, fields are achieved to magnetize said samples of up to 0.13 T (with a maximum deviation of 5% in the limits of the region) and with a low consumption, which allows a portable device.

The susceptometer object of the invention uses a set of permanent magnets for field generation. Unlike the model based on Hallbach cylinders, the susceptometer integrates the magnets within a soft iron structure, that is, with high magnetic permeability, forming a magnetic circuit. This allows direct the magnetic flux inside it.

The complete magnetic circuit is made up of three elements. The central pieces of iron, the magnets, preferably cylindrical, and the final pieces of U-shaped iron. The U-shaped pieces direct the magnetic flux so that it remains confined inside the magnetic circuit.

The central iron pieces are fixed on a structure made of a non-magnetic material so that they remain in fixed positions.

These pieces have two openings, which allow the samples to be magnetized to be introduced. In order to achieve a uniform field in the region where the samples are introduced, the central iron pieces are manufactured forming a spherical cavity, so that the magnetic poles are distributed creating a uniform field inside the opening.

By moving the U-shaped pieces it is possible to vary the field with which the samples are magnetized. Due to its geometry, the flow closure is better due to the U-shaped pieces, so that when separating them from the central pieces, the magnets remain stuck to the U-shaped structure. The position that allows the greatest field is the one that places the magnets glued to the central iron pieces. Starting from that position, as the magnets are separated from the central iron pieces, the air gap between them increases, which increases the reluctance of the magnetic circuit, decreasing the flux inside it and with it the magnetic field. This brings with it a variation in the flow and with it a variation in the magnetic field inside the cavities of the iron pieces where the samples are located.

Samples are inserted into a sample holder, preferably circular in shape, eg into one of the four cylindrical openings. By rotating the sample holder, the samples enter and exit the spherical cavities of the iron parts.

In an example of embodiment, inside said spherical cavities, just in front of each of the iron pieces, there are circular windings, one in front of each metal piece. As the samples enter and exit the spherical cavities, they induces an electromotive force in the windings due to flux variation, given by Faraday's law. This effect allows the measurement of the magnetization of the samples for each magnetization field value:

where £ is the electromotive force appearing in the windings, N is the number of turns in the windings, A is the area of the windings, and B is the field that passes through the area contained by the windings.

By integrating this electromotive force over time, it is possible to obtain a voltage that is directly related to the variation of B through the turns, that is, with the variation of B that the sample produces when it enters and leaves the sample. cavity, with which we can obtain its magnetization:

Brief description of the drawings

To complement the description that is being made and in order to help a better understanding of the characteristics of the invention, a set of drawings is attached as an integral part of said description, where, with an illustrative and non-limiting nature, what has been represented has been following:

Figure 1.- Shows a perspective view of an embodiment of the device object of the invention.

Figure 2.- Shows a schematic top view of the device in figure 1 with the elements that make up the magnetic circuit and without the support structure.

Figure 3.- Shows a perspective view of the elements displayed in figure 2 that make up the magnetic circuit.

Figure 4.- Shows a perspective view and a schematic side view of the iron parts.

Figure 5.- Shows a schematic plan view of the iron pieces with their cavity and facing each other, a sample located between said iron pieces and some measuring secondaries.

Figure 6.- Shows a plan view of an embodiment example of the sample holder.

Preferred embodiment of the invention

Figure 1 shows a perspective of an embodiment of the device object of the invention comprising:

respective U-shaped branches arranged symmetrically and facing each other according to a longitudinal direction of the apparatus, where each one of the U-shaped branches comprises:

- respective pieces of iron (4) comprising a first and a second longitudinal end and configured to face the mineral sample (9) at the first longitudinal end,

- respective permanent magnets (5) located next to the iron pieces (4) according to the longitudinal direction of the apparatus that comprise a first and a second longitudinal end and that have their first longitudinal end facing the second longitudinal end of the iron pieces (4), and

- a U-shaped piece of iron (6) comprising a plate (6.2) placed transversely and two projections (6.1) facing the second longitudinal end of the permanent magnets (5),

a sample holder (2) located between the iron pieces (4) of both U-shaped branches, the sample holder (2) being configured to rotate around a longitudinal axis of the apparatus so that through said rotation it positions the samples (9 ) longitudinally facing the pieces of iron (4).

The exemplary embodiment shown also includes:

- a support structure (1) made of non-magnetic material. The rest of the elements of the apparatus are fixed to this support structure (1), so that it acts as a central support for the system. It is made of a non-magnetic material so as not to disturb the field in the magnetic circuit.

The iron pieces (4) are fixed to said support structure (1) and the U-shaped pieces (6) can slide longitudinally with respect to said support structure (1).

Additionally, in the example shown, the sample holder (2) is fixed to the support structure (1) by means of an axis, so that it can rotate allowing the samples (9) to be introduced or extracted from some spherical cavities (4.1) that the magnetic circuit presents. , where the samples (9) are magnetized.

- at least one motor (3). The example of embodiment shown includes four motors (3) that allow the U-shaped pieces (6) to be moved with respect to the support structure (1), so that the permanent magnets (5) are configured to accompany the movement of the pieces. U-shaped (6) and vary its distance with respect to the iron pieces (4) of the magnetic circuit, so that it is possible to control the intensity of the field.

Therefore, in an embodiment, the apparatus comprises means to vary the distance in the longitudinal direction between the pieces of iron (4) and the permanent magnets (5) so as to achieve a variation in the magnetic field generated by the control of the separation between the permanent magnets (5) and the iron parts (4).

Figure 2 shows a top view of the device where only the components of the magnetic circuit have been highlighted:

Iron pieces (4). These iron parts (4) are manufactured with the face pointing towards the sample holder (2) forming a cavity (4.1) for the introduction of samples (9). More specifically, the cavities (4.1) are spherical so that they achieve a uniform field in the measurement region.

In the exemplary embodiment shown, the iron parts (4) are fixed to the support structure (1) made of the non-magnetic material.

Figure 2 represents the section of these pieces by a plane that cuts the piece along its central axis, so that the spherical cavity (4.1) remains visible.

The permanent magnets (5) allow the generation of a field in the magnetic circuit and the U-shaped pieces (6) close the magnetic circuit, directing the flow in a circular way.

Figure 4 shows a perspective view and a schematic side view of each of the iron pieces (4) that are manufactured with the end pointing to the sample holder (2) in the form of a hemisphere so that a cavity (4.1) is formed. ) spherical between the pair of iron pieces (4).

Figure 5 illustrates the position of the sample (9), the iron parts (4) and the secondaries of measurement (8) when the measurements are made.

Figure 6 shows the sample holder (2) that is fixed to the support structure (1) by means of an axis (10) that allows its rotation. The sample holder (2) comprises at least one cylindrical opening (11) to introduce the samples (9) to be measured, which allows the samples (9) to be introduced into the measurement regions by means of circular movements of the sample holder (2). In the example shown, the sample holder (2) is circular and has four cylindrical openings (11).

The system must be able to measure the magnetization of samples (9) of the specified dimensions and to magnetize these by means of a passive magnetic circuit. The figures show an example of embodiment with the following characteristics:

• The permanent magnets (5) of the magnetic circuit are made of NdFeB with a product BHmax = 38 MGOe of cylindrical shape with dimensions of 20 mm long by 30 mm in diameter.

• The iron parts (4) are made of soft iron with high permeability. In an example of embodiment, the iron pieces (4) are manufactured following the plane of figure 4. On the other hand, the U-shaped iron piece (6), which can be seen in figure 2, presents two cylindrical projections (6.1) of the same dimensions as the permanent magnets (5), 20mm high by 30mm in diameter, where it meets the permanent magnets (5). Said projections (6.1) continue in a platband (6.2) with a thickness of 20 mm. This plate band (6.2) has two threaded grooves on the sides that are attached to two threaded rods, which allow the displacement of the iron pieces (4) bringing the set of permanent magnets (5) and the shaped piece closer or further away. of U (6) to the pieces of iron (4).

• Four stepper motors (3) have been used to move the iron pieces (4). These motors (3) are capable of applying a torque of up to 15 Nm each while maintaining a low peak consumption thanks to their gear ratio. The gear ratio of the motors (3) also allows very precise field control.

• The support structure (1) of the susceptometer has been manufactured with non-magnetic materials. On the one hand, the structure that holds the motors (3) has been made of aluminium. On the other hand, the central structure, with a rectangular shape that has dimensions of 110mm x 180mm with a depth of 30mm, is made of PVC and is where the different components of the susceptometer are attached, as can be seen in figure 1.

• The sample holder (2) has been made of plastic, with a total diameter of 118 mm and a depth of 20 mm and has cylindrical openings (11) of 20 mm in diameter x 20 mm high where the samples will be housed (9). . The cylindrical openings (11) are aligned with the cylindrical iron parts (4) and with the permanent magnets (5), so that the sample (9) that is inside the sample holder (2), when it is moved, remains completely inside the spherical cavity (4.1) formed by the iron pieces (4). The sample holder (2) is attached to the central PVC part of the support structure (1) by means of an aluminum rod with plastic bearings that allow the sample holder (2) to rotate.

• To rotate the sample holder (2) in a controlled manner, a plastic structure to the central PVC structure, which allows to hold a stepper motor connected to a strap. The belt rotates the sample holder (2) by turning. In this case, the stepper motor (3) has a more lax requirement with respect to torque, since it will only have to move the plastic sample holder (2) with the sample inside.

• On the spherical cavities (4.1) of the iron pieces (4) some thin plastic coatings have been coupled, which do not affect the uniformity of the field inside, to allow the secondary windings (8) that they allow the measurement of the magnetization of the samples (9). These secondary windings (8) are each made up of a set of 100 turns of 0.1 mm thick copper wire with a coating to prevent contact. The four reels are connected in series with each other, that is, with the same winding direction, and the terminals of the set are coupled to a female output coaxial connector.

• In one of the spherical cavities (4.1), a small square-shaped precision hall probe of approximately 3mm2 area and 0.5mm width has been included. This probe makes it possible to measure the field with which the samples (9) are magnetized and, together with the motors (3), a precise control of the magnetization field. • The susceptometer is controlled by a PC with a dedicated interface developed in Visual Basic, which communicates with three microcontrollers, for which the pic16F887 models have been used, in charge of controlling the different components of the system.

• On the one hand, it has a microcontroller in charge of controlling the four motors (3), which are powered by the L289 power drivers. • There is another microcontroller in charge of the hall probe measurements. The output of the hall probe is connected to a dedicated board that includes an instrumentation amplifier and various amplification and conditioning stages, allowing accurate reading by the microcontroller.

• Finally, the third microcontroller is in charge of the movement of the sample holder (2), by means of a stepper motor fed through a L298 driver, and of reading the measurements coming from the secondary windings (8), in short, of the magnetization measurement of the samples (9). The output of the secondary windings (8) is connected to an analog integrator, which continues with a set of amplification stages and conditioning, allowing a precise reading of the measure. The integrator allows a direct measurement of the magnetization of the sample (9).

The measurement process consists of two types of movements:

On the one hand, the 90 degree movement, in which the sample (9) starts from the upper position of the sample holder (2) and moves 90 degrees until it is inside the spherical cavity (4.1) where it is magnetized. Subsequently, it moves 90 degrees in the opposite direction, leaving the sample (9) again in the initial position. An integrator separately integrates the 90 degree path introducing the sample (9) and the 90 degree path extracting the sample (9), and later the difference between them is calculated. This difference is proportional to the magnetization of the sample (9), and provides twice as much signal as one of the movements alone.

On the other hand, the movement of 180 degrees. The sample (9) starts from one of the lateral positions, inside one of the spherical cavities (4.1) where it remains magnetized. The sample holder (2) is moved 180 degrees to the opposite spherical cavity (4.1), magnetizing the sample (9) with a field of the same magnitude, but in the opposite direction, and then it is moved back to the initial position. Again, both movements are integrated separately, and then the difference between them is calculated. This difference is proportional to the magnetization of the sample (9), and provides twice as much signal as one of the movements alone. The total signal provided by this movement is double that provided by the movement of 90 and, therefore, allows samples (9) to be measured with more sensitivity.

The susceptometer is calibrated with a coil with a cylindrical geometry and with the maximum dimensions that the samples and a known number of turns. So by controlling the current through the winding, different known magnetic moments can be obtained.

The final result is a susceptometer, which, by means of a passive circuit, is capable of magnetizing the samples (9) with fields of up to 0.13 T with a non-uniformity of less than 6% in the region where the samples are housed. Field control allows a resolution of 0.05 mT in the field variation, with an imprecision of 1%. The size of the samples is limited to the dimensions of the cylindrical openings. of the sample holder (2), 20 mm long by 20 mm in diameter, in the embodiment shown.

Using this device, it has been possible to measure magnetizations of different prospecting mineral samples (9), as well as ferrite samples of known concentrations prepared in a laboratory.

The susceptometer is characterized by being a passive system that generates a uniform magnetic field of up to 0.13T with maximum magnetic field variations of less than 6% in a volume of around 6000 mmA3, in the spherical cavity (4.1).

Alternatively, the susceptometer is characterized by being a passive system that generates a uniform magnetic field of up to 0.13T with maximum magnetic field variations of less than 1% in a volume of 300 mmA3.

The susceptometer is portable, achieving, through the described passive magnetic field generation system, reduced consumption, less than 5 W during the sample measurement process (9). Alternatively, it can present maximum consumption peaks of 25 W when the magnetic field with which the samples are magnetized is modified (9).

Taking all of the above into account, the main contributions of the device object of the invention are based on the fact that, being a portable device:

• Generates magnetic fields that allow working in the range of [0.032 - 0.13] T

• It has a reduced consumption of around 4W in static with punctual peaks of 24 W when the field with which the samples are magnetized is varied.

• Thanks to its low consumption, it can be powered by portable batteries, which makes it portable.

• Allows the characterization of large samples (cylindrical shape up to 20 mm in length and 20 mm in diameter).

• The samples (9) are magnetized with homogeneous magnetic fields in large volumes (with a deviation <6% in volumes of 6000mm3).

• It has a sensitivity greater than 0.22 emu.

Claims (8)

1. Apparatus for measuring the magnetic susceptibility of mineral samples (9), characterized in that it comprises two U-shaped branches arranged symmetrically and facing each other according to a longitudinal direction of the apparatus, where each one of the U-shaped branches comprises: - respective pieces of iron (4) comprising a first and a second longitudinal end and configured to face the mineral sample (9) at the first longitudinal end, - respective permanent magnets (5) located next to the iron pieces (4) according to the longitudinal direction of the apparatus that comprise a first and a second longitudinal end and that have their first longitudinal end facing the second longitudinal end of the iron pieces (4), and - a U-shaped piece of iron (6) comprising a plate (6.2) placed transversely and two projections (6.1) facing the second longitudinal end of the permanent magnets (5), where the iron pieces (4) also comprise, at their first longitudinal end, a cavity (4.1) for the introduction of the samples (9), and four circular secondary windings (8), one on each of the sides of the the cavities (4.1) for the measurement of the magnetization of the samples (9) through the electromotive force that is induced in them due to the movement of the samples (9), where the apparatus also comprises a sample holder (2) located between the iron pieces (4) of both U-shaped branches, the sample holder (2) being configured to rotate around a longitudinal axis of the apparatus so that by said rotation positions the samples (9) longitudinally facing the pieces of iron (4), and where the apparatus comprises means to vary the distance in the longitudinal direction between the pieces of iron (4) and the permanent magnets (5) so that a variation in the generated magnetic field is achieved by controlling the separation between the permanent magnets ( 5) and the iron pieces (4). 2. Apparatus for measuring the magnetic susceptibility of mineral samples, according to claim 1, characterized in that the permanent magnets (5) are made of NdFeB and the iron parts (4) are made of soft iron, forming a magnetic circuit. 3. Apparatus for measuring the magnetic susceptibility of mineral samples, according to claim 1, characterized in that the cavities (4.1) for the introduction of the samples (9) have a spherical geometry, thereby achieving a uniform field inside. 4. Apparatus for measuring the magnetic susceptibility of mineral samples, according to claim 3, characterized in that the cavities (4.1) have maximum dimensions contained in a cylindrical region of up to 20 mm in length and 20 mm in diameter. 5. Apparatus for measuring the magnetic susceptibility of mineral samples, according to claim 1, characterized in that it further comprises: - a support structure (1) made of non-magnetic material, the iron pieces (4) being fixed to said support structure (1) and the U-shaped pieces (6) being longitudinally slidable with respect to said support structure (1), and - a motor (3) configured to linearly move the U-shaped pieces (6) with respect to the support structure (1), so that the permanent magnets (5) are configured to accompany the movement of the U-shaped pieces (6) and vary its distance from the pieces of iron (4). 6. Apparatus for measuring the magnetic susceptibility of mineral samples, according to any one of the preceding claims, characterized in that it comprises a portable battery for its power supply. 7. Apparatus for measuring the magnetic susceptibility of mineral samples, according to any one of the preceding claims, characterized in that the sample holder (2) comprises at least one cylindrical opening (11) for the introduction of the samples (9) to be measured. 8. Apparatus for measuring the magnetic susceptibility of mineral samples, according to claim 7, characterized in that the sample holder (2) is circular and comprises four cylindrical openings (11).