IT202000017425A1 - MAGNETIC DEVICE FOR THE DISSOCIATION OF THE MOLECULES OF A LIQUID STATE SUBSTANCE - Google Patents

Description

MAGNETIC DEVICE FOR THE DISSOCIATION OF THE MOLECULES OF A LIQUID STATE SUBSTANCE

DESCRIPTION OF THE INVENTION

The present invention belongs to the technical sector relating to the chemical-physical dissociation of the molecules of a substance in the liquid state. In particular, the present invention relates to a magnetic device for dissociating the molecules of a substance in the liquid state.

Today, a large percentage of air pollution comes from pollution from motor vehicles.

During fuel combustion, motor vehicles emit a series of polluting substances, such as unburnt hydrocarbons, nitrogen oxides, carbon monoxide, particulate matter.

In recent years, the containment of air pollution caused by motor vehicles? been entrusted to the catalysts, which push the exhaust gases to a further combustion in order to produce more? carbon dioxide and water instead of other polluting substances.

However, to use the catalysts ? should feed the engines with unleaded fuel, since? would the lead determine the gradual and irreversible ?covering? of the active sites of the catalyst itself, not making it more? available to the desired reaction.

Furthermore, since the catalysts are not able to activate at room temperature, the mufflers of motor vehicles have been modified in order to reach in the pi? within the shortest possible time after starting the engine, a temperature of at least 300-350 degrees centigrade.

Consequently, the catalysts are practically ineffective in limiting the emissions of polluting substances from motor vehicles for short journeys with intervals between stops.

In the light of the above, the object of the present invention consists in overcoming the above drawbacks.

The aforementioned purpose? obtained by means of a magnetic device for the dissociation of the molecules of a substance in the liquid state according to claim 1.

Advantageously, the molecules of the substance in the liquid state, traveling through the crossing channel, are affected by the magnetic attraction force determined by the first permanent magnet, the second permanent magnet, the third permanent magnet and the fourth permanent magnet. This magnetic force of attraction has an intensity such as to weaken the force existing between the atoms of the molecules of the substance in the liquid state.

While not wanting to be bound by any physical theory, if the substance in the liquid state is a fuel and the magnetic device, object of the present invention, is arranged upstream of the combustion chamber of a motor vehicle, the inventors have determined that, following the weakening of the force existing between the atoms of the fuel molecules, a uniform mixture is created in the combustion chamber between the fuel molecules and the oxygen, such as to ensure better oxidation of the chemical elements constituting the fuel.

Consequently, on equal terms? of fuel and oxygen used during the combustion process which takes part in the combustion chamber of the motor vehicle, with the magnetic device object of the present invention, ? a reduction in the production of unburned hydrocarbons, and therefore of particulate matter, and nitrogen oxides has been demonstrated, limiting the phenomenon of partial oxidation of the fuel.

Specific embodiments of the invention will be described in the following of the present discussion, in accordance with what is reported in the claims and with the aid of the attached drawings, in which:

- figure 1 and figure 2 are representations in cross section, taken from different section lines, of the magnetic device object of the present invention;

- figure 3-5 are views of some components of the magnetic device object of the present invention;

Figure 6 and Figure 7 are views of the lines of force of the magnetic field determined by the first permanent magnet, the second permanent magnet, the third permanent magnet and the fourth permanent magnet. With reference to the attached drawing tables, ? The generic reference (1) has been indicated for a magnetic device for dissociating the molecules of a substance in the liquid state, comprising: a first container (2) which ? made of non-magnetic material, which ? shaped so as to define a first chamber (2a) and comprising a first through opening (2b) for accessing the first chamber (2a); a second container (3) that ? made of non-magnetic material, which ? shaped so as to define a second chamber (3a) and comprising a second through opening (3b) for accessing the second chamber (3a). The first container (2) and the second container (3) are arranged facing each other so that the first through opening (2b) and the second through opening (3b) are close to each other. between them.

The magnetic device (1), moreover, comprises: a crossing channel (4) which ? interposed between the first through opening (2b) and the second through opening (3b) to be crossed by a substance in the liquid state; a first permanent magnet (5) and a second permanent magnet (6) which are arranged in the first chamber (2a) so as to be side by side; a third permanent magnet (7) and a fourth permanent magnet (8) which are arranged in the second chamber (3a) so as to be side by side; a first element of separation (9) that ? made of non-magnetic material and that ? disposed in the first chamber (2a) and interposed between the first permanent magnet (5) and the second permanent magnet (6) to separate them from each other; a second element of separation (10) that ? made of non-magnetic material and that ? disposed in the second chamber (3a) and interposed between the third permanent magnet (7) and the fourth permanent magnet (8) to separate them from each other.

The first permanent magnet (5) and the third permanent magnet (7) are arranged with each other in such a way that the relative north pole and the relative south pole generate a magnetic field having field lines directed in a first direction (X1) and the second permanent magnet (6) and the fourth permanent magnet (8) are arranged with each other in such a way that the relative north pole and the relative south pole generate a magnetic field having field lines directed in a second direction (X2) which ? opposed to the first verse (X1). Each permanent magnet (5, 6, 7, 8) ? arranged and sized with respect to the other so that the relative north pole and the relative south pole determine a force of magnetic attraction between them having intensity? such as to weaken the force existing between the atoms of the molecules of the substance in the liquid state, during the passage of this substance in the liquid state along the crossing channel (4) (see fig. 1, in which in the crossing channel (4) arrows have been shown which indicate the flow direction of the substance in the liquid state along the crossing channel (4)).

Furthermore, with particular reference to fig.6, the first separation element (9) and the second separation element (10) are arranged so that, in correspondence with these, there is an area not affected: by the field lines, directed in the first direction (X1), of the magnetic field generated by the north pole and the south pole of the first permanent magnet (5) and of the third permanent magnet (7); by the field lines, directed in the second direction (X2), of the magnetic field generated by the north pole and the south pole of the second permanent magnet (6) and the fourth permanent magnet (8).

In other words, during the passage of the substance in the liquid state along the crossing channel (4), this substance in the liquid state will invest? initially the field lines directed in the first direction (X1), the aforementioned zone and the field lines directed in the second direction (X2).

In this way, as a result of the aforementioned area, the substance in the liquid state will be affected of a magnetic reversal of the field lines of the relevant magnetic field.

This area can be understood as an area that is not affected by the field lines generated by the first permanent magnet (5), the second permanent magnet (6), the third permanent magnet (7) and the fourth permanent magnet (8).

In detail, the first permanent magnet (5), the second permanent magnet (6), the third permanent magnet (7) and the fourth permanent magnet (8) are arranged in such a way that the relative north pole and the relative south pole determine a magnetic force of attraction between them having intensity? such as to weaken and/or break the chemical bond existing between the atoms of the molecules of the substance in the liquid state, during the passage of this substance in the liquid state along the crossing channel (4).

With particular reference to figs. 1 and 6, during the passage of the substance in the liquid state along the crossing channel (4), the field lines generated by the first permanent magnet (5), by the second permanent magnet (6), by the third permanent magnet (7) and the fourth permanent magnet (8) are oriented transversely to the direction of flow of the liquid substance.

The relative north pole and the relative south pole of each permanent magnet (5, 6, 7, 8), moreover, can? generate a non-uniform magnetic field having circular field lines such as to strengthen and stabilize the? intensity? of the magnetic attraction force felt by the substance in the liquid state, during the passage of this substance in the liquid state along the crossing channel (4).

The term dissociation, in chemistry, means the partial or complete splitting of a molecule.

By way of example, the substance in the liquid state can? be an internal combustion engine fuel, either petrol or diesel, or water.

In the event that it is desired to dissociate the molecules of a fuel, the magnetic device (1) object of the present invention can be positioned upstream of the engine of a motor vehicle.

The magnetic device (1) object of the present invention can? be a magnetic device for dissociating the molecules of a liquid fuel.

In this case, considering that ferrous particles may be present in liquid fuel, the arrangement of the first permanent magnet (5), the second permanent magnet (6), the third permanent magnet (7) and the fourth permanent magnet (8 ) ? such as to allow a capture of these ferrous particles in correspondence with the area affected by the first permanent magnet (5) and by the third permanent magnet (7), which are opposed to each other.

Consequently, there is an improvement in the operation of the magnetic device (1) object of the present invention, since when the liquid fuel will reach? the area affected by the second permanent magnet (6) and the fourth permanent magnet (8), which are opposite each other, will be? free from ferrous particles.

Alternatively, the magnetic device (1) object of the present invention can be a magnetic device of dissociation of neutral calcium carbonate molecules.

In other words, during the passage of a fuel in the liquid state, or of water, along the crossing channel (4), the first permanent magnet (5), the second permanent magnet (6), the third permanent magnet (7) and the fourth permanent magnet (8) are arranged so that the relative north pole and the relative south pole of each permanent magnet (5, 6, 7, 8) determine a magnetic field perpendicular to the flow of fuel, or of water, such to change the properties? chemical-physical characteristics of the chemical compounds of the fuel or of the water.

In figures 6 and 7, the lines of force of the magnetic field determined by the relative north pole and south pole of the first permanent magnet (5), second permanent magnet (6), third permanent magnet (7) and fourth permanent magnet (8) are depicted. ).

In detail, with reference to fig. 1 and fig. 2, the first container (2) and the second container (3) are arranged facing each other so that the first chamber (2a) and the second chamber (3a) are in communication with each other through the first through opening (2b ) and the second through opening (3b) (see figs.

1 and 2).

Taking into consideration a fuel as a liquid substance and using the magnetic device (1) upstream of the engine of a motor vehicle, the inventors have found the following advantages:

- reduction of the production of particulate following the combustion process; - reduction of the average fuel consumption;

- reduction of the presence of residues from the combustion process in the injectors and in the combustion chamber;

- reduction of impurities? having bacterial load (with relative limitation of proliferation of these) in the injection pump;

- prompt ignition of the engine even at low temperatures.

As proof of the above, the inventors carried out tests using an ?Iveco Stralis 450 CV? (Euro 5 and with registration year 2009) with 950,000 km of travel, automatic gearbox, pump injectors for injection of diesel into the combustion chamber and an average consumption of diesel of 2.8 km per litre.

The tests were conducted to detect diesel consumption, particulate production and general engine efficiency, using the magnetic device (1) object of the present invention upstream of the engine and during operation. of vehicle handling over eighteen months. Therefore, the value shown below ? an average value, determined by the average of the values detected in a month under variable load conditions and variable atmospheric conditions.

AND? a reduction in the production of particulate matter ranging between 60% and 70% and a diesel consumption of a maximum of 3.6 km per litre.

Further tests were carried out using a ?Scania series 4 164 480 CV? (euro 3 and with registration year 2003) with 1100000 km of travel, manual gearbox, traditional injectors for the injection of diesel into the combustion chamber and an average consumption of diesel of 2.7 km per litre. The tests were conducted to detect diesel consumption, particulate production and general engine efficiency, using the magnetic device (1) object of the present invention upstream of the engine and during operation. of handling of the vehicle in the space of a month. Therefore, the value shown below ? an average value, determined by the average of the values detected in a month under variable load conditions and variable atmospheric conditions.

AND? a reduction in the production of particulate matter ranging between 70% and 80% and a diesel consumption of a maximum of 3.4 km per litre.

Further tests were carried out using a ?Fiat Ducato maxi 2800 TD? having 297,000 km of travel, manual gearbox, traditional injectors for the injection of diesel into the combustion chamber and an average consumption of diesel of 9 km per litre.

The tests were conducted to detect diesel consumption, particulate production and general engine efficiency, using the magnetic device (1) object of the present invention upstream of the engine and during operation. of handling of the vehicle over a period of twenty-four months. Therefore, the value shown below ? an average value, determined by the average of the values detected in a month under variable load conditions and variable atmospheric conditions.

AND? a reduction in the production of particulate matter ranging between 70% and 83% and a diesel consumption of a maximum of 12 km per litre.

Taking water into consideration as a liquid substance and using the magnetic device (1) upstream of a tap mixer, the inventors have found the following advantages:

- presence of neutral calcium carbonate having the molecular structure of aragonite;

- greater transparency of the water;

- reduction of the bacterial load of the water.

The first container (2) ? shaped so as to internally define the first chamber (2a) (see figs. 2, 4 and 5).

The first container (2) can? develop along a first axis of longitudinal development (W) (see figs. 2, 4 and 5).

The first chamber (2a) and the first through opening (2b) can also develop along the first longitudinal development axis (W) (see figs. 2, 4 and 5).

The second container (3) ? shaped so as to internally define the second chamber (3a) (see figs. 2, 4 and 5).

The second container (3) can? develop along a second axis of longitudinal development (S).

The first chamber (3a) and the first through opening (3b) can also develop along the second longitudinal development axis (S).

The first axis of longitudinal development (W) and the second axis of longitudinal development (S) can be parallel to each other.

With particular reference to Figure 2, the first axis of longitudinal development (W) and the second axis of longitudinal development (S) are shown as emerging from the drawing table.

By way of example, the crossing channel (4) can? receiving a fuel supply line to a motor vehicle engine.

The crossing channel (4) can? have a circular section.

The first permanent magnet (5) and the second permanent magnet (6) can be arranged in the first chamber (2a) so as to be side by side along the first longitudinal development axis (W) (see fig.1).

The second permanent magnet (7) and the fourth permanent magnet (8) can be arranged in the second chamber (3a) so as to be side by side along the second longitudinal development axis (S) (see fig.1).

The first permanent magnet (5) and the third permanent magnet (7) can be arranged so that they face each other with respect to the crossing channel (4) (see fig.1).

The second permanent magnet (6) and the fourth permanent magnet (8) can be arranged so that they face each other with respect to the crossing channel (4) (see fig.1).

With particular reference to figure 1, the position of the first permanent magnet (5) and of the second permanent magnet (6) in the first chamber (2a) and the position of the third permanent magnet (7) and of the fourth permanent magnet (8) in the second room (3a) ? such as to outline a pattern you have a rectangular shape. In other words, again with particular reference to figure 1, the first permanent magnet (5) and the fourth permanent magnet (8) are positioned along a diagonal of this scheme having a rectangular shape; while, the second permanent magnet (6) and the third permanent magnet (7) are positioned along the other diagonal of this scheme having a rectangular shape.

The first container (2) and the second container (3) can each have the shape of a C and are arranged so as to be specular (see figs. 1, 2 and 4).

The first container (2) and the second container (3) can be made in separate bodies and can be identical to each other.

Preferably, the first container (2), the second container (3), the first separation element (9) and the second separation element (10) are made of plastic material.

Advantageously, the first container (2), the second container (3), the first separation element (9) and the second separation element (10) are not affected by the magnetic attraction force determined by the first permanent magnet (5), by the second permanent magnet (6), the third permanent magnet (7) and the fourth permanent magnet (8) (see fig.2).

The first chamber (2a) and the second chamber (3a) can have a square or rectangular cross section.

The first chamber (2a) and the second chamber (3a) can have such a shape as to determine a shape coupling between the first chamber (2a) with the first permanent magnet (5) and the second permanent magnet (6) and between the second chamber (3a) with the third permanent magnet (7) and the fourth permanent magnet (8).

The first container (2) can? have a first edge (20) at which ? arranged the first through opening (2b) and a second edge (200) which ? opposed to the first edge (20) (see figs. 2, 4 and 5).

The first chamber (2a) ? closer to the first edge (20) than to the second edge (200) (see Figs. 2, 4 and 5).

The second container (3) can? have a third edge (30) at which ? arranged the second through opening (3b) and a fourth edge (300) which ? opposed to the third edge (30) (see fig.2).

The second chamber (3a) ? closer to the third edge (30) than to the fourth edge (300) (see fig.2).

The second container (3) ? equal to the first container (2) and, for this reason, you can? refer to figs. 4 and 5 also for the second container (3).

Preferably, the first permanent magnet (5), the second permanent magnet (6), the third permanent magnet (7) and the fourth permanent magnet (8) have a polygonal section.

Advantageously, the first permanent magnet (5), the second permanent magnet (6), the third permanent magnet (7) and the fourth permanent magnet (8) are shaped in such a way as to allow a form coupling with the first chamber (2a) and the second chamber (3a).

The section of the first permanent magnet (5), of the second permanent magnet (6), of the third permanent magnet (7) and of the fourth permanent magnet (8) can? be square or rectangular.

The first permanent magnet (5), the second permanent magnet (6), the third permanent magnet (7) and the fourth permanent magnet (8) can each define a parallelepiped having six faces.

Furthermore, the magnetic device (1) can? comprising a hollow container (11) arranged to laterally envelop the first container (2) and the second container (3); a first closure plate (12) which ? arranged at a first end? (2c, 3c) of the first container (2) and of the second container (3) and a second closure plate (13) arranged at a second end? (2d, 3d) of the first container (2) and of the second container (3); fastening means (14) for fastening the first closure plate (12) and the second closure plate (13) to the first container (2) and to the second container (3) (see figs. 1 and 3).

The fastening means (14) can comprise screws which can be screwed between the first closure plate (12) and the second edge (200) of the first container (2) and between the first closure plate (12) and the fourth edge (300) of the second container (3).

Similarly, the fastening means (14) can comprise screws which can be screwed between the second closure plate (13) and the second edge (200) of the first container (2) and between the second closure plate (13 ) and the fourth edge (300) of the second container (3) (see fig.1).

Furthermore, part of the screws of the fastening means (14) can be screwed between the hollow container (11) and the second edge (200) of the first container (2) and between the hollow container (11) and the fourth edge (300) of the second container (3) (see fig.1).

In this motion, the screws of the fastening means (14) do not contact the first permanent magnet (5), the second permanent magnet (6), the third permanent magnet (7) and the fourth permanent magnet (8) but develop at the inside of the second edge (200) of the first container (2) and of the fourth edge (300) of the second container (3).

The hollow container (11), the first closure plate (12) and the second closure plate (13) can keep the first container (2) and the second container (3) close together.

The first permanent magnet (5), the second permanent magnet (6), the third permanent magnet (7) and the fourth permanent magnet (8) can have a magnetic induction value between 0.3 and 0.60 Tesla.

The first closing plate (12) and the second closing plate (13) can comprise a relative through hole (12a, 13a) shaped to be crossed by the crossing channel (4) (see figs. 1 and 3).

With particular reference to fig. 1, the crossing channel (4) passes through the through hole (12a) of the first closure plate (12) and the through hole (13a) of the second closure plate (13) so as to be placed interposed between the first container (2 ) and the second container (3).

The hollow container (11) can? be formed by two half-shells (11a, 11b) which can be coupled together.

In detail, the inventors have demonstrated that optimal results can be obtained when the first permanent magnet (5), the second permanent magnet (6), the third permanent magnet (7) and the fourth permanent magnet (8) have a section square or rectangular and a length value between 2-10 cm, the first separator element (9) and the second separator element (10) have, respectively, a length value between 0.1-1 cm and in the case where: the first permanent magnet (5) and the second permanent magnet (6) are arranged in the first chamber (2a) so as to be distant 1 cm, respectively, from the first end? (2c) and from the second end? (2d) of the first container (2); the third magnet (7) and the fourth magnet (8) are arranged in the second chamber (3a) so as to be distant 1 cm, respectively, from the first end? (3c) and from the second end? (2d) of the second container (3).

The magnetic device (1) object of the present invention can? comprise further permanent magnets and further separating elements (not shown) which can be arranged side by side with the first permanent magnet (5) (or with the second permanent magnet (6), alternately with each other, in the first chamber (2a) and which can be placed side by side with the third permanent magnet (7) (or with the fourth permanent magnet (8)), alternately, in the second chamber (3a).

Thus, you will have an increase in length of the magnetic device (1), keeping the length and section of each permanent magnet and the length and shape of each separation element equal to each other.

Claims (7)

1. Magnetic device (1) for the dissociation of molecules of a substance in a liquid state, in which: does it include a first container (2) which ? made of non-magnetic material, which ? shaped so as to define a first chamber (2a) and comprising a first through opening (2b) for accessing the first chamber (2a); does it include a second container (3) which ? made of non-magnetic material, which ? shaped so as to define a second chamber (3a) and comprising a second through opening (3b) for accessing the second chamber (3a); the first container (2) and the second container (3) are arranged facing each other so that the first through opening (2b) and the second through opening (3b) are close to each other? between them; does it include a crossing channel (4) which ? interposed between the first through opening (2b) and the second through opening (3b) to be crossed by a substance in the liquid state; comprises a first permanent magnet (5) and a second permanent magnet (6) which are arranged in the first chamber (2a) so as to be side by side; comprises a third permanent magnet (7) and a fourth permanent magnet (8) which are arranged in the second chamber (3a) so as to be placed side by side; does it include a first separation element (9) which ? made of non-magnetic material and that ? disposed in the first chamber (2a) and interposed between the first permanent magnet (5) and the second permanent magnet (6) to separate them from each other; does it include a second separating element (10) which ? made of non-magnetic material and that ? disposed in the second chamber (3a) and interposed between the third permanent magnet (7) and the fourth permanent magnet (8) to separate them from each other; the first permanent magnet (5) and the third permanent magnet (7) are arranged with each other so that the relative north pole and the relative south pole generate a magnetic field having field lines directed in a first direction (X1); are the second permanent magnet (6) and the fourth permanent magnet (8) arranged with each other in such a way that the relative north pole and the relative south pole generate a magnetic field having field lines directed in a second direction (X2) which ? opposed to the first line (X1); each permanent magnet (5, 6, 7, 8) ? arranged and sized with respect to the other so that the relative north pole and the relative south pole determine a force of magnetic attraction between them having intensity? such as to weaken the force existing between the atoms of the molecules of the substance in the liquid state, during the passage of this substance in the liquid state along the crossing channel (4). 2. Magnetic device (1) according to the preceding claim, wherein the first container (2) and the second container (3) each form a C shape and are arranged so as to be specular. 3. Magnetic device (1) according to any one of the preceding claims, wherein the first container (2), the second container (3), the first separation element (9) and the second separation element (10) are made of plastic material. 4. Magnetic device (1) according to any one of the preceding claims, wherein the first permanent magnet (5), the second permanent magnet (6), the third permanent magnet (7) and the fourth permanent magnet (8) have a polygonal section . 5. Magnetic device (1) according to any one of the preceding claims, wherein: the first permanent magnet (5), the second permanent magnet (6), the third permanent magnet (7) and the fourth permanent magnet (8) each define a parallelepiped having six faces. 6. Magnetic device (1) according to any one of the preceding claims, comprising: a hollow container (11) arranged to laterally wrap the first container (2) and the second container (3); a first closure plate (12) which ? arranged at a first end? (2c, 3c) of the first container (2) and of the second container (3) and a second closure plate (13) arranged at a second end? (2d, 3d) of the first container (2) and of the second container (3); fastening means (14) for fastening the first closure plate (12) and the second closure plate (13) to the first container (2) and to the second container (3). 7. Magnetic device (1) according to any one of the preceding claims, wherein the first permanent magnet (5), the second permanent magnet (6), the third permanent magnet (7) and the fourth permanent magnet (8) have a value of magnetic induction between 0.3 and 0.60 Tesla.