FR3140443A1 - Electric charge absorber, load sensor and magnetometer - Google Patents

Abstract

Electric charge absorber, charge sensor and magnetometer The present invention relates to an absorber (10) of electrical charge from the environment, the absorber (10) comprising a diamagnetic element (12) surrounded by an insulator (14), the the insulator (14) being an insulating envelope with respect to electromagnetic radiation. Figure for abstract: figure 1

Description

Electric charge absorber, load sensor and magnetometer

The present invention relates to an electric charge absorber. The present invention also relates to a load sensor, a magnetometer comprising such an absorber and to a use of such a device.

BACKGROUND OF THE INVENTION

Measuring electrical charge is important for many applications.

However, the devices currently used are unable to accurately measure weak electrical charges,

There is therefore a need for devices making it possible to measure weak electrical charges with better precision.

For this purpose, the description describes an absorber of electrical charge from the environment, the absorber comprising a diamagnetic element surrounded by an insulator, the insulator being an insulating envelope with respect to electromagnetic radiation.

According to particular embodiments, the absorber has one or more of the following characteristics, taken in isolation or in all technically possible combinations:

- the diamagnetic element is made of a diamagnetic material which is chosen from the list constituted, without it being limiting by:

- money,

- pyrolytic carbon, in plate or sintered powder,

- an organic compound, in particular sucrose, and

- the water.

- the diamagnetic element has a cylindrical shape.

- the diamagnetic element is a cylindrical bar provided with two ends, a first end being an open end and a second end closed by a paramagnetic element.

The description also describes a load sensor, the sensor comprising an absorber as previously described and an electromagnetic wave guide comprising a conduit, the conduit preventing the propagation of standing waves, the conduit extending between two ends, one end being the diamagnetic element.

According to particular embodiments, the load sensor has one or more of the following characteristics, taken in isolation or in all technically possible combinations:

- the other end of the conduit is a reflecting parabola.

- the sensor further comprising a removable shutter, the shutter being made of a paramagnetic material, for example aluminum.

The description also concerns a magnetometer comprising:

- an electrode mounted to rotate around an axis, the electrode being a hemispherical electrode made of a diamagnetic material,

- a sensor as previously described, the sensor being movably mounted on a slide arranged between the sensor and the electrode,

- a measurement sub-assembly suitable for measuring the distance between electrodes during the deviation of the electrode caused by a movement of the sensor, the value of the magnetic field measured by the magnetometer being the measurement distance and

- a discharge sub-assembly capable of discharging the electrical charge from the electrode when part of the discharge sub-assembly is in contact with the electrode.

According to particular embodiments, the magnetometer has one or more of the following characteristics, taken in isolation or in all technically possible combinations:

- the hemispherical electrode is a black body.

- the subassembly comprises an electrically conductive element made of ferromagnetic material to carry out the discharge.

- the discharge subassembly comprises an insulating enclosure made of a paramagnetic material.

- the measuring sub-assembly includes a light sensor.

- the magnetometer further comprises a mast to which the electrode is connected, and a device for maintaining the direction of the mast.

- the magnetometer further comprises an arm connecting the electrode to the mast, the arm being made of a paramagnetic material.

The description also describes a use of a magnetometer as previously described, the charges resulting in particular from a natural induction produced by a living organism, in one of the following applications:

- measurement of the diamagnetic charge of at least part of a living organism, such as a human being, a plant or of an organic compound, such as an essential oil,

- measurement of the diamagnetic charge of an ore, for example an ore found in the path of a stony ground,

- followed by the germination of a seed,

- storage and transfer of diamagnetic energy, for deferred therapeutic use, for example skin care or fire barrier.

- determination of the degree of freshness of a food, such as a fruit, vegetable, meat or fish,

- measurement of the charge remanence of a living organism subjected to electromagnetic radiation, in particular electromagnetic radiation coming from a mobile terminal,

- detection of diamagnetic gradients in a soil, and

- mapping of the diamagnetic gradients of a soil, signatures of archaeological deposits present or disappeared, such as feudal mottes, arches, stair steps, ancient routes, protohistoric huts.

In this description, the expression “specific to” means indifferently “adapted for”, “adapted to” or “configured for”.

Characteristics and advantages of the invention will appear on reading the description which follows, given solely by way of non-limiting example, and made with reference to the appended drawings, in which:

- there is a schematic representation of a electric charge absorber,

- there is a schematic representation of a electrical load sensor,

- there is a schematic representation of a magnetometer, and

- there is a schematic representation of part of the magnetometer of the .

DETAILED DESCRIPTION E OF PREFERRED EMBODIMENTS

An absorber 10 is illustrated on the .

The absorber 10 is here an electrical type absorber, that is to say an absorber of electrical charge from the environment.

The absorber 10 comprises a diamagnetic element 12 surrounded at least partly by an insulator 14 of electromagnetic radiation.

As its name indicates, a diamagnetic element 12 comprises a part made of diamagnetic material.

Diamagnetism is a behavior of materials which leads them, when subjected to a magnetic field, to create a very weak magnetization opposed to the external field, and therefore to generate a magnetic field opposite to the external field. When the field is no longer applied, the magnetization disappears.

Several materials can be considered for the diamagnetic material.

For example, 935 silver or an organic compound, such as sucrose, can be considered.

According to yet another embodiment, the diamagnetic material is water.

In this case, it is a silver wire having undergone machining by cutting and polishing the ends.

However, preferably, when greater compactness is sought, the diamagnetic material chosen is pyrolytic carbon which has the advantage of having a relatively high diamagnetic susceptibility, this amounting to -40.10 ^-5 . This corresponds to a size reduction of 20 compared to the case where the diamagnetic material chosen is silver.

Pyrolytic carbon (or pyrocarbon) is a synthetic material (non-existent in nature) similar to graphite, but with covalent bonds between its graphene layers due to imperfections during its production. It is generally produced by heating a hydrocarbon near its decomposition temperature (thermolysis), and allowing the graphite to crystallize (pyrolysis). One method is to heat synthetic fibers in a vacuum. Another method is to place seeds in the very hot gas in order to cover them with a graphite deposit.

According to the example described, the diamagnetic element 12 is a solid cylinder made of diamagnetic material.

The cylinder has a height between 3 millimeters (mm) and 20 mm.

According to the example described, the height is equal to 10 mm.

The cylinder also has a basic shape, which is a disk in the case of the .

The disc has a diameter of between 1 mm and 10 mm.

According to the example proposed, the diameter is equal to 2 mm.

The charge and discharge time constant is proportional to the mass of the cylinder.

The diamagnetic element 12 is thus a cylindrical bar provided with two ends 16 and 18.

The first end 16 is an open end and the second end 18 is closed by a paramagnetic element not shown on the .

Paramagnetism designates in magnetism the behavior of a material medium which does not possess spontaneous magnetization but which, under the effect of an external magnetic field, acquires a magnetization oriented in the same direction as the applied magnetic field. A paramagnetic material has a magnetic susceptibility of positive value.

The insulator 14 serves to strongly attenuate external electromagnetic radiation (such as visible or infrared light rays) to ensure that the diamagnetic element 12 can absorb the electrical charge from the immediate environment of the absorber 10.

It can be noted here that the insulator 14 thus serves to modify the radiation pattern which is a function of the solid opening angle.

The insulator 14 is, here, an insulating envelope with respect to electromagnetic radiation.

According to the example illustrated, insulator 14 is made of aluminum.

In particular, the insulator 14 is here a flexible aluminum film in contact with the diamagnetic element 12.

Alternatively, the insulator 14 is, in the case of the , a hollow cylinder surrounding the diamagnetic element 12.

The absorber 10 described is thus an absorber capable of effectively absorbing the electrical charge from the environment.

The absorber 10 can be seen as a diamagnetic mass probe capable of acquiring and storing a potential. The diamagnetic element 12 will thus keep in memory the charge captured by the environment.

This capacity can be advantageously exploited to acquire or measure the electrical charge. For this, it is described in what follows a load sensor 20 of electromagnetic energy is thus described with reference to the .

The load sensor 20 comprises an absorber 10 and an electromagnetic wave guide 22.

Due to the nature of the absorber 10, the sensor 20 is a low load load sensor.

The electromagnetic waveguide 22 comprises a conduit 24 and a shutter 26.

The conduit 24 has a curved profile without a straight bend in order to avoid the propagation of standing waves.

The conduit 24 has walls 28 made of insulating material.

The insulating material is, for example, poly(ethylene terephthalate). Such a material is more often referred to by the abbreviation PET.

Alternatively, the insulating material is a resin, in particular a resin suitable for additive manufacturing or plastics molding.

According to the example described, the conduit 24 has the same sectional shape, which is that of a ring for which an interior diameter and an exterior diameter can be defined.

This conduit 24 is wound around a cylinder 30.

The internal diameter is between 1 mm and 3 mm, preferably equal to 2 mm.

The outer diameter is between 3 mm and 5 mm, preferably equal to 4 mm.

As the diameters are relatively small, the conduit 24 can be described as capillary.

The length of conduit 24 is between 10 cm and 100 m.

In addition, the conduit 24 does not have bends having a radius of curvature greater than or equal to 10 mm.

The conduit 24 extends between two ends 24A and 24B, one end 24A being the diamagnetic element 12 and the other end 24B being the shutter 26.

The shutter 26 makes it possible to close or not the conduit 24, the shutter 26 making it possible to isolate the sensor 20 from the outside.

Shutter 26 is removable.

The shutter 26 is made of a paramagnetic material, such as aluminum for example.

The sensor 20 further comprises a protective housing 32 surrounding the absorber 10, the conduit 24 and the shutter 26.

The sensor 20 is, in addition, provided with a parabola 34.

Parabola 34 is a reflecting parabola.

The sensor 20 also includes an index 35 making it possible to locate the position of the sensor 20.

It can be noted here that the sensor 20 has a relatively low mass, the mass being less than or equal to 2 grams.

In operation, the sensor 20 is thus designed to charge in less than 10 milliseconds and memorize a charge without alteration by conduction. The sensor 20 is, in particular, insensitive to the external environment and particularly to radiation oriented mainly along the main axis of the sensor 20.

This advantageously makes it possible to determine a low amplitude load with relatively good precision, for example with a magnetometer 36 as described with reference to the .

The magnetometer 36 is a device for the electric charge of a body.

The magnetometer 36 is thus suitable for measuring the value of the magnetic field generated by a body.

The magnetometer 36 comprises the sensor 20 described above, a displacement sub-assembly 38, a sensing sub-assembly 40, a measurement sub-assembly 42 and a discharge sub-assembly 44.

All the elements of the magnetometer 36 rest on a support 46 for which an end 48 can be defined.

The support 46 extends perpendicular to the vertical direction which is identified by an axis Z on the .

The support 46 thus extends in a plane for which a first transverse direction can be defined (marked by an axis ) and a second transverse direction (marked by a Y axis on the ). The X and Y axes are chosen to form a direct orthonormal coordinate system.

In the remainder of the description, to facilitate understanding, the first transverse direction will be called first transverse direction X, the second transverse direction will be called second transverse direction Y and the vertical direction will be called vertical direction Z.

The movement subassembly 38 is a slide 38.

The slide 38 is arranged between the end 48 of the support 46 and the capture sub-assembly 40.

The slide 38 extends along the first transverse direction X.

The sensor 20 is movably mounted on the slide 38.

The slide 38 is thus arranged to lead the sensor 20 to the capture sub-assembly 40.

For this, the sensor 20 can be driven by hand by an operator.

Alternatively, the sensor 20 is driven by a motorized plate. The motor used to move the sensor 20 is a stepper motor, for example equipped with a 200 steps per revolution encoder.

To locate the position of the sensor 20 along the first transverse direction

The capture sub-assembly 40 is represented more precisely on the in the resting position.

The capture subassembly 40 comprises an electrode 50, a mast 52, a holding device 54 and an arm 56.

The electrode 50 is a hemispherical electrode made of a diamagnetic material 12.

In a specific embodiment, the electrode 50 is a hollow half-sphere with a diameter of 30 mm and has a wall of 0.4 mm.

The electrode 50 is made of a very absorbent material, for example a black resin.

Electrode 50 here forms a black body.

The electrode 50 is rotatably mounted around the mast 52.

The mast 52 extends in a main direction, called the direction of the mast 52.

As visible on the , the direction of the mast 52 is the vertical direction Z.

The holding device 54 is capable of maintaining the direction of the mast 52. The holding device 54 is, for example, a stirrup 54.

The stirrup 54 is, for example, made integral with the support 46 to guarantee good stability of the mast 52.

The electrode 50 is thus rotatably mounted around the vertical axis Z.

Arm 56 connects electrode 50 to mast 52.

The arm 56 extends in the rest position in the second transverse direction Y.

The arm 56 is made of a paramagnetic material, such as silver.

The arm 56 is, according to a specific example, a foil having a length of 70 mm. The length is the dimension along the second transverse direction Y.

As visible on the , the foil has a width less than the diameter of the electrode 50, typically 25 mm.

Such an example of a capture sub-assembly 40 allows the movement of the sensor 20 to generate a movement of the electrode 50. The capture sub-assembly 40 thus, in a certain way, captures the charge stored by the sensor 20.

The movement described by the electrode 50 is thus a portion of a circle around the vertical direction Z.

The portion of the circle is limited to an angle of 60°, so that the deviation of the electrode 50 is between 0° and 60.

The measuring subassembly 42 is capable of measuring the deviation of the electrode 50 caused by a movement of the sensor 20, the value of the magnetic field depending on this deviation.

The law relating the value of the magnetic field and the deviation is not linear and was previously determined for the magnetometer 36.

This law is parabolic in shape.

According to the specific example described, the measurement subassembly 42 comprises a photovoltaic cell capable of detecting when the deviation of the electrode 50 caused by a movement of the sensor 20 exceeds a predefined threshold, for example equal to 45°.

Alternatively, according to another example, the measurement subassembly 42 includes a light sensor.

The photovoltaic cell is capable of obtaining the position of arm 56 by determining the position where the light coming from a light plane is obscured by arm 56.

Knowing the position of the arm 56 allows us to know its angular deviation which corresponds to the angular deviation of the electrode 50.

The value of the magnetic field measured by the magnetometer 36 is linked to the deviation measured by the aforementioned law.

The discharge subassembly 44 is capable of discharging the electrical charge from the electrode 50.

Such a discharge takes place when part of the discharge subassembly 44 is in contact with the electrode 50.

According to the example described, the discharge subassembly 44 comprises a conductive element 58.

The conductive element 58 is an electrical conductive element made of ferromagnetic material making it possible to capture the charge of the electrode 50.

The discharge subassembly 44 also includes an enclosure 60 which is an insulating enclosure made of a paramagnetic material.

The enclosure 60 also serves the capture subassembly 48 since the enclosure 60 plays a screening role by avoiding electromagnetic disturbances coming from the outside.

Such a magnetometer 36 allows determination of a low amplitude charge with relatively good precision.

The magnetometer 36 which has just been described can advantageously be used for numerous applications.

In particular, the magnetometer 36 can be used to measure electro-biological quantities, that is to say electromagnetic fields emitted by an organism living in a space, such as an animal, a plant or a bacteria, fields whose amplitude is eminently small. In particular, the electric field, charge or impedance can be determined.

Thus, as a particular example, the magnetometer 30 can be used to measure the diamagnetic charge of at least part of a living organism, such as a human being, a plant or of an organic compound, such as an oil. essential.

With this capacity, it can be envisaged to use the magnetometer 30 for any application based on the knowledge of an electro-biological quantity.

It can be cited in particular the monitoring of the germination of a seed.

As another example, the determination of the degree of freshness of a food, such as a fruit, vegetable, meat or fish, can also be cited.

According to yet another example, the measurement of the charge remanence of a living organism subjected to electromagnetic radiation, in particular electromagnetic radiation coming from a mobile terminal, can be cited.

As another example, the devices can also be used for the detection of diamagnetic gradients in a soil. Therefore, the magnetometer 36 can be used to search for present or disappeared archaeological deposits having left their mark by a residual diamagnetic charge and ancient pathways due to the fact that cosmic rays tend to diamagnetize the ground. This diamagnetization loses its homogeneity when man makes constructions.

It can be noted here that the sensor is also operational in an urban environment. This sensor produces no artifacts when passing over a cast iron manhole cover, or between parked cars.

According to yet another example, these devices can also be used in alternative medicine.

In fact, these devices make it possible to store and transfer diamagnetic energy, in particular through skin care or fire blocking.

Otherwise formulated, such a device could produce a therapeutic effect equivalent to that of a magnetizer.

In fact, the magnetizer has a diamagnetic charge concentrated in its palms. By performing movements close to an affected area of a patient, a charge transfer occurs from the magnetizer to the patient. Currently the magnetizer works in the presence of the patient in his office.

With the devices described, the charge transfer would take place via a buffer tank, for delayed treatment. It could also be considered that the extent of the transfer zone be controlled by the use of a parabola with a controllable focal length.

Claims (10)

Absorber (10) of electrical charge from the environment, the absorber (10) comprising a diamagnetic element (12) surrounded by an insulator (14), the insulator (14) being an insulating envelope with respect to electromagnetic radiation. Absorber according to claim 1, in which the diamagnetic element (12) is made of a diamagnetic material chosen from the list consisting of:
- money,
- pyrolytic carbon, and
- an organic compound, in particular sucrose,
- the water. Absorber according to claim 1 or 2, in which the envelope is made of aluminum. Absorber according to any one of claims 1 to 3, in which the diamagnetic element (12) is a cylindrical bar provided with two ends (16,18), a first end (16) being an open end and a second end ( 18) closed by a paramagnetic element. Load sensor (20), the sensor (20) comprising:
- an absorber (10) according to claim 4, and
- an electromagnetic wave guide (22) comprising a conduit (24), the conduit (24) preventing the propagation of standing waves, the conduit (24) extending between two ends, one end (24A) being connected to the diamagnetic element (12) and the other end (24B) has a removable shutter (26). Sensor according to claim 5, in which the shutter (26) is made of a paramagnetic material, for example aluminum. Magnetometer (36) comprising:
- an electrode (50) rotatably mounted around an axis (Z), the electrode (50) being a hemispherical electrode made of a diamagnetic material, the electrode (50) being, preferably, a black body,
- a sensor (20) according to any one of claims 6 to 9, the sensor (20) being movably mounted on a slide (38) arranged to lead the sensor (20) to the electrode (50),
- a measuring sub-assembly (42) capable of measuring the deviation of the electrode (50) caused by a movement of the sensor (20), the value of the magnetic field measured by the magnetometer (36) being proportional to the measured deviation , the measurement sub-assembly (42) comprising, for example, a light sensor, and
- a discharge sub-assembly (44) capable of discharging the electrical charge from the electrode (50) when part of the discharge sub-assembly (44) is in contact with the electrode (50). Magnetometer according to claim 7, in which the discharge subassembly (44) comprises at least one element chosen from:
- a conductive element (48), the conductive element (48) being a ferromagnetic material, and
- an enclosure (60), the enclosure (60) being an insulating enclosure made of a paramagnetic material. Magnetometer according to claim 7 or 8, in which the magnetometer (36) further comprises:
- a mast (52) to which the electrode (50) is connected, and
- a holding device (54) for the mast (52),
the magnetometer (36) further comprising, preferably, an arm (56) connecting the electrode (50) to the mast (52), the arm (56) being made of a paramagnetic material. Use of a magnetometer (30) according to any one of claims 7 to 9 in one of the following applications:
- measurement of the diamagnetic charge of at least part of a living organism, such as a human being, a plant or of an organic compound, such as an essential oil,
- followed by the germination of a seed,
- determination of the degree of freshness of a food, such as a fruit, a vegetable, a meat or a fish,
- measurement of the charge remanence of a living organism subjected to electromagnetic radiation, in particular electromagnetic radiation coming from a mobile terminal, and
- detection of diamagnetic gradients in a soil.