ITTO950263A1 - DEVICE FOR THE MAGNETIC TREATMENT OF A FLOW OF LIQUID AND CONSTRUCTION UNIT TO BE USED IN THE DEVICE. - Google Patents

Abstract

The device is equipped with coupled construction units (1), mounted externally on a section of pipe. Each unit is equipped with a permanent magnet (2, 3) with magnetic induction greater than 0.005 Tesla, measured at a radial distance of 50 mm from the central longitudinal phase of the relative unit (1). The same pole (N) of all the magnets (2, 3) is each time turned towards the liquid that must flow through the section of pipe. A single construction unit (1) has two permanent magnets (2, 3), one of which is housed with an oblique position within the housing (4) of the unit (1). On the external side the two magnets (2, 3) are equipped with magnetizable plates (21, 31). For fastening to a section of pipe, the casing (4) is equipped with flanges (41) with holes (42). This device has a higher performance than comparable physical water treatment devices. The construction units (1) improve the efficiency of the crushing and / or pulverization of the mineral conglomerates existing in the water.

Description

Description accompanying a patent application for an Industrial Invention entitled: Device for the magnetic treatment of a liquid flow and construction unit to be used in the device.

Description

The invention relates to a device for the magnetic treatment of a liquid according to the preamble of claim 1, as well as a construction unit to be used in such a device according to claim 16.

Devices of this kind are known in numerous variants and are offered for sale or used preferably for the physical treatment of water.

Most of the known water treatment devices have a structure in the form of finished modules in the form of a tubular element with mounted magnets. In order to be able to work with particularly small permanent magnets, which have a reduced field intensity, the magnets are normally arranged in the internal part of the tubular element or of the device.

These devices are mounted under normal conditions in the water supply ducts and treat the water that passes through them in a known way. The purpose of these devices consists in crushing and / or pulverizing the mineral conglomerates present in the water, i.e. the conglomerates formed by calcium and magnesium carbonates, so that, for example, limescale deposits can be avoided or at least significantly reduced.

In practice, however, it is found that many of these known devices do not function satisfactorily. Moreover, many of the known devices have a very expensive structure from the mechanical point of view and therefore also have a corresponding expensive manufacture. The devices which are made according to the shape of a tubular element must also be adapted to the relative diameter of the tubular duct; that is, at any point in which such a device is to be used for the physical treatment of water, a constructive size of the device must be available which is specifically adapted to the diameter of the tubular duct. Finally, the dimensions of these devices are generally relatively large, so that the latter cannot often be installed, or at least not absolutely in existing systems or in the water supply duct.

A device for the magnetic treatment of a fluid is known from CH-PS678721. This device has an outer surface of a tubular shape, in which a magnet device with rod-shaped magnets is arranged in a central position, so that between the inner side of the casing and the central arrangement of the magnets an empty space is formed. annular. End elements are arranged on both ends of the cladding which are provided with channels arranged transversely to the longitudinal axis of the cladding and connect the annular void space with the inlet or outlet of the device. These channels cause the fluid to pass through the magnets in a helical line shape through the liner or void.

In the case of this device, the disadvantage is that it is expensive to manufacture and that due to the connection channels which have a narrow cross-section, a strong pressure drop is generated, particularly in the case of high flow crossing speeds, due to which such a device is only suitable for relatively small quantities of water. Furthermore, this device has the drawback that at high flow crossing speeds, due to the reduced section, the efficiency is considerably worsened.

The object of the invention is therefore to improve a device for the magnetic treatment of a liquid according to the preamble of claim 1 in such a way that it has a higher efficiency than comparable devices, that it can be produced economically and that by means of the arrangement of the magnets does not lead to any variation in section in the tubular duct.

This problem is solved by the properties reported in the characterizing part of claim 1.

A device formed by a plurality of individual permanent magnet construction units, in which the construction units are mounted externally on a tubular section, can be connected to an existing duct network. This is provided that the section of tube on which the constructive groups with the magnets are mounted is made of a non-magnetizable material.

Through tests it has been surprisingly found that the best result is obtained from the point of view of crushing and / or pulverization of the mineral conglomerates present in the water when in all the magnets used each time the same poles are turned towards the liquid passing through. The tests have also shown that further better results are obtained as regards the crushing and / or pulverization of the mineral conglomerates present in the water when the magnetic induction of the permanent magnets used, at a radial distance equal to 50 mm in the longitudinal median zone. of its constructive unit, amounts to at least 0.005 Tesla. This occurs in particular when the pipe section has a diameter of 5 cm and more. Since the poles of the permanent magnets are turned towards the liquid passing through, the magnetic field lines develop predominantly in a perpendicular direction to the direction of the water flow, which involves a better efficiency than in the case in which the poles some magnets are arranged parallel to the flow of the liquid passing through them.

Preferred embodiments of the invention are described in the subordinate claims 2 to 15.

In the tests it was also found a further surprising effect, and precisely the fact that an even better result is obtained when each time the magnetic north poles of all the magnets are turned towards the liquid passing through them.

In another preferred embodiment of the device it is also provided that the construction units have openings, through which elements used for fastening are guided. In this way the individual building units can be joined together in the simplest way to form a group.

Another object of the invention consists in proposing a construction unit with at least one permanent magnet, which can be used in a device according to one of claims 1 to 15.

Preferred embodiments of this constructive unit are described in the subordinate claims 17 to 25.

In the following an example of embodiment of the invention will be described in greater detail on the basis of the drawings, in which:

Figure 1 shows a section of a tubular section with two construction units with magnets shown schematically in the drawing and mounted externally;

figure 2 shows a longitudinal section of a pipe section with four construction units with magnets shown schematically in the drawing and mounted externally;

Figure 3 shows a single construction unit with magnet in a longitudinal section, illustrated in detail; And

Figure 4 shows a section of the construction unit with magnet of Figure 3.

Figure 1 shows a section of a length of pipe 8 with two construction units 1 mounted externally, which are shown schematically. Each constructive unit 1 has two permanent magnets 2, 3, which are spaced from each other and are housed in a casing 4. The length 1 of such a constructive unit 1 is equal to a multiple of its height h. From this representation, two construction units 1 can be seen as a whole, in which, regardless of the pipe diameter, another even number of construction units 1 can be applied to the pipe section 8 1. The north pole N of each magnet 2, 3 it faces towards the section of pipe 8 and therefore towards the passing liquid. The magnetic field lines, which are shown in the drawing by way of evidence by means of interrupted lines 5, essentially develop in a direction perpendicular to the direction of the flow r of the liquid. In order to minimize the mutual effect of the magnetic field lines 5, the construction units 1, as shown in the drawing, can be moved relative to each other in the longitudinal direction of the pipe section 8. In the case of construction units 1 which do not have a symmetrical shape, it is also possible to arrange a construction unit 1 rotated with respect to the other by 180 ° around its vertical axis, which will be described in greater detail below.

The fixing of the individual construction units 1 can take place, for example, by means of a fixing wire or connecting elements for cables, which, however, are not shown in the drawing to facilitate a more evident representation. In order to connect or fix the construction units 1 by means of the fastening elements, the latter are provided with holes through which the fastening elements can be guided.

The magnetic induction of a single magnet 2, 3 is equal to approximately 0.015 Tesla, measured at a radial distance of 50 SUD in the area of the longitudinal average part of the relative construction unit, since in the tests it was found that crushing and / or a reliable pulverization of the mineral conglomerates present in the water only when the magnetic induction is greater than 0.005 Tesla in the range in which the physical effect is intended.

On the basis of Figure 2, a section of tube 8A with a larger diameter can be seen. On this length of pipe 8A four construction units 1, 1A are assembled as a whole, which are also shown schematically. The four construction units 1, 1A are arranged with a star-shaped distribution on the outer surface of the tubular section 8A, while each time two construction units 1; 1A are arranged diametrically opposite each other. By means of this arrangement it is ensured that the magnetic field lines 5A, which are also illustrated schematically, are distributed practically homogeneously for each section of the pipe section 8A, so that the whole means crossing is physically treated. The number of construction units 1, 1A arranged on the outer surface of the pipe section 8A naturally varies with the diameter of the pipe section 8A.

From figure 3 it is possible to see in detail in a longitudinal section a single constructive unit 1, enlarged with respect to figures 1 and 2. The constructive unit 1 has a casing 4 in which two permanent magnets 2, 3 are housed. Both permanent magnets 2, 3 are provided on both sides with magnetizable plates 21, 31, and the latter protrude beyond each magnet 2, 3 in the area of its two front sides. These plates 21, 31 serve to align and concentrate the magnetic field lines. The alignment and concentration of the magnetic field lines can also be facilitated by means of the housing 4, in that the latter is partly formed of a magnetizable material. In the present case, both side walls as well as the lid of the Enclosure are made of a ferritic material. In order to fix the two magnets 2, 3 in the casing 4, the intermediate compartments are filled by casting with a two-component mass 44.

One of the two magnets 2 is aligned and fixed in the housing 4 in such a way that its longitudinal axis 22 forms an angle a of approximately 2 ° with the longitudinal axis 15 of the construction unit 1, while the other magnet 3 is aligned in such a way that its longitudinal axis extends parallel to the longitudinal axis 15 of the construction unit 1 or coincides with the latter. The plates 31 of the last magnet 3 protrude beyond the front sides of this magnet 3 on the side facing the other magnet 2, more than in the case of the side opposite to the other magnet 2. In tests it was found that by the arrangement o the execution of the magnets 2, 3 described above, it is possible to considerably improve the efficiency as regards the crushing and / or pulverization of the mineral conglomerates.

On both sides, the housing 4 of the construction unit 1 each time has a fixing flange 41, which each time has three holes 42 mentioned above for guiding the fastening elements through them.

In figure 4 the constructive unit 1 is finally illustrated in a section along the line Ά-Ά (figure 3). It appears evident from this representation that the single magnet 3 has a certain distance with respect to the surface of the bottom of the constructive unit 1 which must be set up towards the section of pipe 8, 8A (Figures 1 and 2).

On the surface of the bottom which must face the pipe section, the construction units 1 can also be provided with a cavity, as shown by means of a line 43 shown interrupted in the drawing. Such a cavity serves to center the construction units 1 and also allows to optimize the distance between the magnets 2, 3 and the tubular section. The depth and shape of the cavity 43 can in this case vary and on the other hand can be adapted to the diameter of the pipe section.

The most important interventions or the most important embodiments of a constructive unit 1 will be further explained below:

1. alignment of the magnets 2, 3 in the casing 4, in such a way that each time the same pole N, S, in particular the north pole N, faces the surface of the bottom of the casing 4 and therefore in the condition assembly is facing the liquid passing through;

2. oblique positioning of one of the two permanent magnets 2, 3 housed in a constructive unit 1;

3. magnetic induction of the single permanent magnet 2, 3 greater than 0.005 Tesla, measured at a radial distance of 50 mm in the area of the longitudinal central part of the relative constructive unit;

4. magnetizable plates 21, 31, which are arranged on both sides of the magnets 2, 3 and when the magnet 3 faces parallel to the longitudinal axis 15 of the construction unit 1, the front sides of this magnet 3 protrude more on the side facing the other magnet 2 than the side facing the other magnet 2.

By each of these interventions or these embodiments of such a constructive unit, it is possible to improve the efficiency as regards the crushing and / or pulverization of the mineral conglomerates.

Furthermore, it has been found that the construction units 1, in which a magnet 2, as described above with reference to point 2, is arranged in an oblique position, these units are preferably arranged externally on the pipe section in such a way that the construction units 1 arranged diametrically opposite each other are rotated with respect to each other according to their vertical axis and according to 180 °. In this way, each time a magnet 2 arranged obliquely is found in front of a magnet 3, aligned parallel to the longitudinal axis 15 of the construction unit 1, which in turn improves the efficiency.

Naturally, it is also possible to think of embodiments of construction units 1 which have, for example, only a magnet 2, 3. These construction units 1 preferably have the characteristics indicated in points 1 and 3 as well as the magnetizable plates 21, 31 reported in point 4, which are arranged on both sides of a magnet 2, 3.

Claims (25)

CLAIMS 1. Device for the magnetic treatment of a liquid, with a section of tube (8, 8A) formed by a non-magnetizable material, through which the liquid flows, and with a plurality of construction units (1, 1A) each with at least a permanent magnet (2, 3), characterized by the combination of the following characteristics: - the construction units (1, 1A) are mounted on the outside of the tubular section (8, 8A); - the two poles (N, S) of each permanent magnet (2, 3) are aligned perpendicular to the direction (R) of the liquid flow; - each time the same pole {N, N) of each permanent magnet (2, 3) faces the liquid, while the other pole (S, S) of each permanent magnet (2, 3) faces the liquid each time opposite direction with respect to the liquid; - the magnetic induction of each permanent magnet (2, 3) is equal to at least 0.005 Tesla at a radial distance of 50 mm in the area of the longitudinal central part of the relative construction unit. 2. Device according to claim 1, characterized in that each time the magnetic north pole (N) of each permanent magnet (2, 3) faces the flowing liquid. 3. Device according to claim 1 or 2, characterized in that each construction unit (1, 1A) has two magnets (2, 3), which are housed within a casing (4) and are spaced from each other . Device according to claim 3, characterized in that the longitudinal axis (22) of a magnet (2) forms an angle (a) with the longitudinal axis (15) of the construction unit (1), while the axis longitudinal axis of the other magnet (3) runs parallel to the longitudinal axis (15) of the construction unit (1) or coincides with it. 5. Device according to claim 4, characterized in that the angle (a) is between 1 and 5 °. Device according to one of the preceding claims, characterized in that a magnetizable plate (21, 31) is arranged on both longitudinal sides of each magnet (2, 3). 7. Device according to claim 6, characterized in that each plate (21, 31) protrudes beyond both front sides of the corresponding magnet (2, 3). Device according to one of claims 4 to 7, provided that the latter refers to claim 3, characterized in that the plates (21, 31) of the magnet (3) facing parallel to the longitudinal axis (15) of the construction unit (1) protrude beyond this magnet (3) on the side facing the other magnet (2) more than they protrude on the side opposite the other magnet (2). Device according to one of the preceding claims, characterized in that the length (1) of a construction unit (1) is equal to a multiple of its height (h). Device according to one of the preceding claims, characterized in that at least one pair of construction units (1, 1A) is used for each pipe section (8), while the construction units (1, 1A) with the magnets of a copy they are arranged diametrically opposite each other. Device according to one of claims 1 to 9, characterized in that the individual construction units (1) are arranged opposite each other on the pipe section (8) and are displaced relative to each other in the longitudinal direction of the pipe section (8). 12. Device according to claim 10, provided that the latter refers to claim 4, characterized in that the constructive units (1, 1A) arranged diametrically opposite each other are arranged externally on the section of tube (8) in such a way that they are rotated with respect to each other by 180 ° around their vertical axis. Device according to one of the preceding claims, characterized in that an even number greater than two of construction units (1, 1A) distributed in the shape of a star on the outer surface of the pipe section (8) is used. Device according to one of the preceding claims, characterized in that each constructive unit (1) has a cavity (43) on the inner side which must face the pipe section (8, 8A), which serves for centering and / or to optimize the distance of each magnet (2, 3) with respect to the pipe section (8, 8A). Device according to one of the preceding claims, characterized in that each construction unit (1) is provided with fixing flanges (41) with openings (42), through which elements which serve for fixing can be guided. Construction unit (1) with at least one permanent magnet (2, 3) for use in a device according to one of the preceding claims. Construction unit (1) according to claim 16, characterized in that this has two permanent magnets (2, 3) which are spaced apart from each other. Construction unit (1) according to claim 17, characterized in that the longitudinal axis (22) of a magnet (2, 3) forms an angle (a) with the longitudinal axis (15) of the construction unit. Construction unit (1) according to claim 18, characterized in that the angle (a) is comprised between 1 ° and 5 °. Construction unit (1) according to one of claims 16 to 19, characterized in that a magnetizable plate (21, 31) is arranged on both longitudinal sides of each magnet (2, 3). Construction unit (1) according to claim 20, characterized in that the plates (21, 31) project beyond the two front sides of the corresponding magnet (2, 3). 22. Construction unit (1) according to one of claims 18 to 21, provided that the latter refers to claim 16, characterized in that the plates (31) of that magnet (3), whose longitudinal axis coincides with the longitudinal axis (15) of the construction unit (1) or runs parallel to it, protrude beyond the magnet (3) on the side facing the other magnet (2) more than they protrude on the side opposite the other magnet (2). Construction unit (1) according to one of claims 16 to 22, characterized in that the length (1) of a construction unit (1) is a multiple of its height (h). Construction unit (1) according to one of claims 16 to 23, characterized in that each construction unit (1) has a cavity (43) on the inner side which is to face the pipe section (8), which it is used for centering and / or to optimize the distance of each magnet (2, 3) with respect to the section of pipe (8). Construction unit (1) according to one of claims 16 to 24, characterized in that each construction unit (1) has fixing flanges (41) provided with openings (42).