DE29805550U1 - Device for conditioning a medium - Google Patents

Description

RALF M. KERN.'D^. DjET^R

llegen

Riding Stable Icking

Description

Device for conditioning a medium

The invention relates to a device for conditioning a medium.

The effective quantity, physically called magnetic or electrical vector potential, is inherently contained in an electro- and permanent-magnetic field and is directed perpendicular to the actual field, e.g. the magnetic field.

Vector potentials quantum physically influence the atomic or molecular structure or internal orientation of media within their range of influence, especially moving media.

The object of the invention is to create an optimally economical device with which media are interacted and/or conditioned by vector potentials for a specific use, namely with a form of vector potentials that is as maximally intensified as possible, whereby

conditioning can also be used during use.

The media can be solid, liquid or gaseous, whereby the effect of the vector potentials can vary accordingly. The invention particularly covers aqueous and hydrocarbon systems and mixtures thereof, but also solid substances in preferably powdery or granular form, as well as solid substances in other forms with, for example, uneven or unbalanced energy distribution, whereby catalysis-like effects can also occur.

Accordingly, the invention primarily consists of a device for conditioning a medium,
in which the medium is subjected to the influence of a magnetic or electric field of practically free vector potentials before and/or during its intended use.

The vector potentials must be able to exert their effect as completely or largely free or exposed as possible from the influence of the surrounding magnetic or electric fields.

In this case, a carrier medium can also first be subjected to the effect of the vector potentials and then the effect of the vector potential can be transferred from the carrier medium to the medium to be used as intended.

It is also essential to the invention that the medium or the carrier medium is kept anticlockwise or clockwise in one flow direction at least in the vector potential range.

In particular in magnetic vector potential treatment, the influence of the relative velocity of the medium to the vector potential range and the treatment temperature are also important.

It is also advantageous if the medium in the vector potential range is subjected to oscillation, preferably sound and/or electromagnetic and/or swirling mixing.

For example, by structuring water using vector potentials, it is possible to separate or separate out the finest impurities, e.g. to form colloids.

An improvement in the mutual influence of a medium or the interaction of two or more media can be achieved if a process partner is supplied to the medium before or within the vector potential range, preferably also if this is separately conditioned in a vector potential range before the combination.

In general, the conditioning of media according to the invention can effectively improve a variety of reactions or effects

of the treated media, which result from the quantum physical change of their atomic or molecular structure.

The internal structural transformation of the medium that occurs under the influence of the vector potentials is noticeable, among other things, in a reduction in the surface tension or viscosity, whereby a variety of advantageous effects can be achieved.

A device for carrying out the aforementioned methods is characterized by a plurality of permanent magnets arranged close to one another or adjacent to one another around a media passage, which are oriented in their surface direction with their polarity alternately S/N or N/S magnetically, wherein the permanent magnets lying adjacent to one another are arranged with poles (S/N or N/S) alternating in the flow direction of the medium in the passage.

The electromagnetic other variant of the device according to the invention is characterized by at least one electrical toroidal coil and at least one passage arranged on its side surface for the medium already to be exposed to the electromagnetic vector potential.

A further significant advantageous influence on the media in terms of effectiveness can be achieved with the features of claims 7 to 10. It can also be advantageous that with these devices

Also, vortex waves can be generated that roll over or circulate in the flow direction of the medium.

The invention is explained in more detail below in several embodiments. It shows

Figure 1 shows a permanent magnetic
Transformer device schematically in
Longitudinal section,

Figure 2 is a schematic cross-sectional view
along A - A in Figure 1,

Figure 3 shows a first embodiment of a

inventive electromagnetic
Transformer device schematically in
Longitudinal section,

Figure 4 shows a second embodiment of a

Transformer device according to the invention,
schematically in longitudinal section,

Figure 5 is an enlarged schematic side view of a spiral or helical
Guide.

The permanent-magnetic transformer device 1 has a plurality of magnets 2, 3, which open a passage 4 through which a tube 5 projects, on which the magnets 2, 3 are arranged close to one another in such a way that, if possible, one of two

adjacent magnets according to Figure 2 in the radial direction with the S-PoI around the passage 4 and with the N-PoI radially outwards and the other magnet reversely magnetized.

Towards the passage 4 and radially outwards, the poles N-S and S-N alternate, i.e. in the axial and flow direction and also along the radially outer circumferential surface of the disk-shaped magnets 2 and 3.

Due to the close proximity of the different magnetic poles, the magnetic field lines between them are short-circuited and lie closely along their poles, so that the vector potentials are directed into the tube 5 or exposed into the media flow.

The individual disk-shaped magnets 2 and 3 can have a round central passage 4 and round peripheral contours as shown in Figure 2 or can also be designed differently, e.g. with a rectangular passage and rectangular peripheral contours.

If the compactly arranged magnets 21, 3 are enclosed by an outer housing shell 8, which leaves a radially outer passage 7 free between their radially outer peripheral surface 6 formed by the magnet edges, it is possible to provide bypass openings 12 instead of a central inlet 10 through which the medium is diverted from a radially outer inlet 11 along the radially outer peripheral surface 6 into the tube 5.

and in this up to the outlet 9 to subject it to a renewed vector potential treatment in the central passage 4. A coaxial variant of the inlet and the outlet is shown in Figure 5.

Alternatively, another medium 40 can be introduced into the transformer device 1 through the radially outer inlet 11 and, after vector potential treatment along the radially outer circumferential surface 6, can be fed through the bypass opening 12 to another medium flowing in through the axially central inlet 10.

In a similar manner, the second medium 42 or additional media 42 can be supplied to the flowing media stream through a separate inlet (42).

Different flow velocities can be set by both the central flow through the vector potential areas and the radial outer flow.

Within the passage cross-sections, helical guides 13 or baffles 14 (see Figures 1 and 5) can also be provided, which give the flowing medium 40 a specific left or right twist or spin.

Figure 3 shows an electromagnetic transformer device 20 in which electrical toroidal coils 22 to 24 are provided within a housing 21.

are provided on the side surfaces 27 and 28 of which passages 29 are provided through which the medium 40 can flow either in one passage or in several deflected passages along the regions of the vector potentials 33 from the inlet 30 to the outlet 31.

These passages 29 can also be provided with spiral-shaped guide plates 14 (Figures 1 and 5), which not only serve to increase the homogeneous mixing of the media(s) 40 and additional media 42 that can also be mixed in, but above all to generate an optional left- or right-hand twist or spin of the media flow. These can also cause a circulating turbulence transverse to the flow direction (see Figure 5).

The toroidal coils 22 - 24 consist of electrical wire windings that are as close to one another as possible (as indicated schematically with 34), which, after a coil course of 360°, are each connected by electrical connections 25, 26 to a power source (not shown), preferably to direct current, which can also pulsate, however. The toroidal coils 22 to 24 necessarily form a round body, so that a top view can be dispensed with.
The direction of the vector potentials 33 acting from the side surfaces 27 and 28 is determined by the winding direction of the toroidal coil and by the direction of the current, whereby oppositely directed vector potentials cancel each other out. The magnetic field in each toroidal coil, which is based on the 3-finger rule, runs in the

"V"

• « · 1

Interior 32 of the toroidal coils, so that the vector potentials from the side surfaces of the toroidal coils can be effective practically without a magnetic field.

In the electromagnetic transformer device 20 shown in Figure 4, the passages 29 are arranged in the form of hoses between, for example, two toroidal coils 22 and 23 in the area of the densest vector potential effect, whereby the spiral arrangement of the hose windings also influences the chiral effect on the medium - whether left- or right-handed. A second medium 42 - or similar others - can be added through an inlet 41.

Figure 5 shows a further modified form of the transformer device 1 according to Figure 1, in which the central inlet 10 for the medium 40 in the central passage 4 is designed as a coaxial guide with the outlet of the medium flowing back via the radially outer passage 7 on the radially outer circumferential surface 6 of the magnets.

Spiral guide plates 38 are provided on the peripheral surface 6, between whose radially outer edge and the inside of the outer casing shell 8 a gap 39 is provided as a means for forming vortices 35. These vortices are created by calculating the flow at the outer edge of the guide plates 14 or 38 and can increase the influence of the vector potential areas on the medium.

The illustrated use of magnetic

Vector potentials for structuring media include

also the analogous use of electrical vector potentials.

List of reference symbols

1 = Permanent magnetic transformer device

2 = N/S magnets

3 = S/N magnets

4 = Central passage in ring disc shape as in Figure 2,

radially directed N/S or S/N magnetized

5 = tube

6 = Radial outer circumferential surface

7 = Radial outer passage

8 = Outer casing

9 = Outlet

10 = Central inlet

11 = Radial outer inlet

12 = Flow openings

13 = Spiral or helix guide

14 = Baffles

20 = Electromagnetic transformer device

21 = Housing

22 = Electric toroidal coil

23 = Electric toroidal coil

24 = Electric toroidal coil

25 = Electrical connections

26 = Electrical connections

27 = Side surfaces of the 22 -

28 = Side surfaces of the 22 -

29 = Passages

30 = entrance

31 = Outlet

«&lgr; tm ·' ■··· ·· «t

32 = Interior of the toroidal coil

33 = Vector potentials

34 = Coil path

35 = vertebra

38 = Means for rotating the medium flow

39 = vortex forming agent 4 0 = medium

41 = Inlet for added medium

42 = Added media

Claims (11)

1. Device for conditioning a medium, characterized by a plurality of permanent magnets ( 2 and 3 ) arranged close to one another or adjacent to one another at a medium passage ( 4 ), which are oriented in their surface direction with their polarity alternately S/N or N/S magnetically, wherein the permanent magnets ( 2 , 3 or 3 , 2 ) adjacent to one another are arranged with poles (S/N or N/S) alternating in the flow direction of the medium in the passage. 2. Device according to claim 1, characterized in that the passage ( 4 ) is arranged in the inner region of the permanent magnets ( 2 , 3 ). 3. Device according to one of claims 1 and 2, characterized in that an outer passage ( 7 ) is provided around the permanent magnets ( 2 , 3 ). 4. Device according to claim 2 and 3, characterized in that the passage ( 4 ) in the inner region of the permanent magnets ( 2 , 3 ) and the outer passage ( 7 ) are connected in series one behind the other. 5. Device according to one of claims 2 to 4, characterized in that in the passage ( 4 ) in the inner region and/or in the outer passage ( 7 ) means ( 33 ) are provided which guide the medium ( 40 ) in a certain chirality or direction of rotation (left- or right-handed) through the vector potential regions. 6. Device for conditioning a medium, characterized by at least one electrical toroidal coil ( 22-24 ) and at least one passage ( 29 ) arranged on its side surfaces ( 27 , 28 ) for the medium to be exposed to the electromagnetic vector potential range. 7. Device according to claim 6, characterized in that the passage ( 29 ) is arranged on both side surfaces ( 29 ) of the toroidal coil ( 22-24 ). 8. Device according to claim 6, characterized in that several toroidal coils ( 22-24 ) with rectified vector potentials are arranged parallel to one another and the passages ( 29 ) for the medium ( 40 ) are arranged between them. 9. Device according to one of claims 6-8, characterized in that the passages ( 29 ) are arranged in a spiral direction (clockwise or counterclockwise). 10. Device according to one of claims 6-9, characterized in that means ( 33 ) for achieving a rotating flow of the medium ( 40 ) in a certain direction of rotation (left or right) are provided in the interior of the passages ( 4 , 7 , 29 ). 11. Device according to one of claims 8 to 10, characterized in that the means are designed as vortex-forming means ( 33 ), in particular circulating in the flow direction of the medium within the passages ( 4 , 7 , 29 ) for the medium ( 40 ).