WO2000025856A1 - Method and device for compensating electrosmog - Google Patents

Abstract

The present invention relates to a method for compensating the electromagnetic radiation which is harmful for the human organism, i.e. the electrosmog. A metallic structure in the shape of a Möbius ring forming a closed conductive loop is used for converting the abiotic electromagnetic radiation into an electromagnetic radiation having an inverted Poynting vector <U>P</U>. The conductive loop essentially comprises two different conductive parts preferably having the same length.

Description

Name: Method and device for the compensation of electrosmog

Our living and working world today is increasingly dominated by electrical devices. From the coffee machine at home to the PC at work, electrical devices have found their way into almost all areas of everyday life. At the same time, the exposure to unwanted and unavoidable electromagnetic radiation has increased continuously. The frequency range of this electromagnetic radiation ranges from low-frequency 50 Hertz, which can originate, for example, from high-voltage lines, to high-frequency radiation in the range of several hundred megahertz, the source of which are modern PCs, up to the highest frequencies in the range of gigahertz and above, for example from Mobile phones are emitted. Even if the concrete consequences of the effects of electromagnetic radiation on the human organism have not yet been fully clarified, there is still broad agreement that people's living and working areas should remain largely free of exposure to electromagnetic radiation. This has led to safety regulations for the operation of mobile phones, for example, as well as safety regulations for microwaves for use in the home kitchen. In this context, the regulations on emissions from PC monitors are also worth mentioning. In the home area, experiments are sometimes even being carried out with the completely voltage-free switching of electrical lines in the living area.

The object of the present invention is a method and a device for compensating electromagnetic radiation which is harmful to the human organism, hereinafter referred to as electrosmog. The object is achieved by the method described in claim 1 and by the devices described in claims 2, 3 and 4.

The present invention is based on the basic hypothesis that every cell of a living organism contains fluctuating dipole moments which, in their interaction, increase a macroscopic electromagnetic field of a single cell. These electromagnetic fields can be detected by medical measurement technology. Examples of this are the EKG, the EEG, or the EMG. The hypothesis on which the invention is based is that all cells of an organism must oscillate at a uniform frequency. According to this hypothesis, a healthy, vital organism is characterized in that the frequencies of the individual cells match and that the individual cells oscillate in phase with one another. External interference fields can lead to a disturbance of this collective vibration and thus impair the well-being of the organism concerned. Depending on the strength of the disturbance, the interference fields can lead to simple ailment, depression, reduced vitality, and in the case of strong interactions between interference fields and the body's own rhythms, can also lead to serious impairments such as illnesses or even death.

Studies by the rhythm expert H. B. Breithaupt from the Institute for Occupational Physiology and Rehabilitation Research at the University of Marburg show that biological rhythms satisfy nonlinear vibrational equations. An undisturbed biological oscillator stabilizes itself on a certain working frequency. This working frequency has a certain value in a healthy organism. If external interference radiation acts on such a non-linear oscillator, the interaction between the oscillator and interference leads to a shift in the operating frequency of the non-linear oscillator. This can lead to the operating frequency of the biological oscillator being shifted into a so-called abiotic range. In this context, an abiotic area is a frequency range that can lead to impairments of the organism.

A comparison of the field strengths of biological fields with those of technical interference fields shows that very weak technical interference fields reach the same field strength as biological fields. Even with very weak external disturbances, a reaction on the human organism can be expected. Due to the large number of technical sources of interference, it is not possible to eliminate the causes of the so-called electrosmog, ie the exposure to electromagnetic interference. Accordingly, a method and a device are required which lead to the electromagnetic waves of an electrical device, which are inevitably emitted during the operation of electrical devices, no longer being able to have a harmful effect on a human organism. This is the starting point of the present invention. The present invention relates to a method and a device by means of which the interference radiation emitted by electrical devices is absorbed and converted into a new form of radiation which can no longer interact with the oscillations of individual cells in an organism. The basic element of the invention is a special conductor geometry, which converts electromagnetic interference fields radiated from the outside into electromagnetic fields of special topology by means of induction and radiates them again. The conductor in which a current is induced due to the external interference radiation has the shape of a Möbius ribbon (Augustus Möbius, astronomer and mathematician, 1790 - 1868). This means that the band, which is closed to form a ring, makes a rotation through 180 ° about its longitudinal axis during a complete revolution. If one calculates the current induced in the ring, one finds that it is purely imaginary. This purely imaginary, time-varying current in turn leads to the emission of electromagnetic fields again, whereby the solution of the Maxwell equations shows that the role of the electric field E and the magnetic field H are just reversed in the radiated field. This leads to an inversion of the associated Poynting vector P, which can also be interpreted clearly as an inversion of the field energy. It is clear from this that the field emitted by an Möbius band-like conductor configuration through which induction current flows has such a field distribution that it can no longer interact with a biological oscillator, which is a source and an absorber of conventional electromagnetic fields. The consequence of this is that an abiotic effect of the electromagnetic interference radiation is no longer to be feared, since coupling to the oscillations of the cells of a human organism is no longer possible.

The effect of the device according to the invention is thus based on an absorption of the harmful interference radiation and its transformation into electromagnetic radiation with an inverted Poynting vector. If two counter-rotating Möbius band-like conductors are used as a device for compensating for electrosmog, the additional positive effect is achieved that the magnetic field lines resulting from the superimposition are closed and can no longer penetrate into the fields of biological oscillators.

In October 1998 by Dr. med. J. Prinz, Kassel prepared expert opinions on the physiological parameters of test subjects at a computer workstation with and without device according to the invention for the compensation of electrosmog, the effectiveness of the device for the compensation of electrosmog could be demonstrated.

Further features and advantages can be found in the subclaims and in the following non-restrictive description of exemplary embodiments, which are explained in more detail with reference to the drawing. In this show:

1 is a perspective view of a Möbius band-like metallic conductor,

2: a plan view of a ring made of two metallic conductors,

3: a top view of a ring from FIG. 2 which is deformed to the right to form an “eight”,

4: a top view of a ring from FIG. 2 which is deformed to the left to form an "eight",

5: a plan view of a right-handed radiation device, consisting of an "eight" from FIG. 3 deformed into a double ring, which represents a right-handed Möbius band-like conductor loop,

6: a plan view of a left-handed radiation device, consisting of an "eight" from FIG. 4 deformed into a double ring, which represents a left-handed Möbius band-like conductor loop,

7: a basic circuit diagram of a device for the compensation of electrosmog, consisting of two conductively connected radiation devices according to FIGS. 5 and 6,

8: a basic circuit diagram of a further device for the compensation of electrosmog, consisting of two conductively connected radiation devices according to FIGS. 5 and 6,

9: a basic circuit diagram of a further device for the compensation of electrosmog, again consisting of two conductively connected radiation devices according to FIGS. 5 and 6, 10: a basic circuit diagram of a further device for the compensation of electrosmog, consisting of two conductively connected radiation devices according to FIGS. 5 and 6,

11 shows a basic circuit diagram of a device for compensating for electrosmog, based on the device shown in FIG. 7 with an additional antenna and earth connection,

12: a basic circuit diagram of a device for the compensation of electrosmog, based on the device shown in FIG. 8 with an additional antenna and ground connection,

13 shows a basic circuit diagram of a further device for compensating for electrosmog, based on the device shown in FIG. 7 with an additional antenna and earth connection, diodes being inserted into the connecting line,

FIG. 14: a basic circuit diagram of a further device for the compensation of electrosmog based on the device shown in FIG. 13, a further ground connection being present, and

15: a basic circuit diagram of a further device for the compensation of electrosmog, consisting of two emitting devices from FIGS. 5 and 6, which are conductively connected via two connecting lines, diodes being inserted into the connecting lines and a grounding and an antenna connection being present are.

1 shows a Möbius band-like conductor loop for use as a radiation device for an electromagnetic field with inverted Poynting vector P in the method according to the invention for compensating for electromagnetic interference fields of the belt by 180 ° with a complete circulation. Rotations through 180 ° ± nx 360 ° are also possible, where n is a natural number or zero. The conductor loop can, for example, consist of a thin metal sheet (for example copper sheet with a thickness of less than 10 mm, preferably less than 1 mm and a width which is at least five times the thickness, in particular ten times) the thickness is made), their diameter can be between 1 mm and far more than 1 m.

The basic body of a radiation device 2 of a further device according to the invention for the compensation of electrosmog 1 can be seen from FIG. 2. This consists of two metal conductors 28 and 29 which are conductively connected to one another and which are electrically conductively connected to one another at the connection points 21 and 22, forming a closed, in particular annular structure. The metallic conductors 28 and 29 can be provided with an electrical insulation layer or also have an electrically conductive surface.

This annular base body is now twisted into a structure which has the geometric shape of an eight, as shown in FIGS. 3 and 4. At the intersection 27 that arises, the conductor pieces 28 and 29 can be electrically insulated from one another or also have an electrically conductive connection. In particular, the twisting is carried out in such a way that both the resulting first loop 23 with the center 25, which is at the top in FIGS. 3 and 4, and the second loop 24 with the center 26, which is at the bottom in FIGS. 3 and 4, comprise approximately equal lengths of the conductor pieces 28 and 29. The base body can be rotated clockwise (Fig. 3) or counterclockwise (Fig. 4).

In a further step, the base bodies rotated to the right or left are deformed in such a way that the center points 25 and 26 of the first 23 and second 24 conductor loops essentially coincide. This is shown in Figures 5 and 6. This creates the Möbius tape-like conductor loops according to the invention, which are used as radiation devices 2 in all further exemplary embodiments of the device according to the invention for the compensation of electrosmog 1. The conductors 28 and 29 deformed into radiating devices 2 can touch or not be in contact.

Possible electrical block diagrams of devices according to the invention for the compensation of electrosmog 1 are shown in FIGS. 7 to 10. Two radiating devices 2 rotated in opposite directions are connected to one another at their connecting points 21 or 22 in different configurations in an electrically conductive manner via a metallic connecting line 3. The exemplary embodiments shown in FIGS. 7 to 10 show an implementation the device for the compensation of electrosmog 1 claimed from claim 2 embodiment a) to d)

In all of the following exemplary embodiments of a device according to the invention for the compensation of electrosmog 1, an antenna connection 4 and an earth connection 5 are provided. In practice, these connections 4 and 5 are used to connect an antenna 41 and a ground 51 in an electrically conductive manner. The connection to the antenna 41 can already be made during the manufacture of a device according to the invention for the compensation of electrosmog 1, the connection to a ground 51 is generally made at the location of the intended use of the device 1.

In all of the following exemplary embodiments, an antenna 41 connected to the antenna connection 4 and an earth connection 51 connected to the earth connection 5 serve in particular to likewise compensate for the electromagnetic radiation which is always present with the network frequency of generally 16.6, 50 or 60 Hertz.

A possible electrical basic circuit diagram of a device according to the invention for the compensation of electrosmog 1 is shown in FIG. 11, which is based on the device 1 shown in FIG. 7. The free connection point 22 of the first radiation device 2 is electrically conductively connected to an antenna connection 4. The free connection point 22 of the second radiation device is electrically conductively connected to a ground connection 5. For the sake of clarity, the antenna 41 and grounding 51 connected to the connections 4 and 5 in practical use of the device 1 are indicated by dashed lines. This embodiment is claimed in claim 3.

A further possible basic electrical circuit diagram of a device according to the invention for the compensation of electrosmog 1 is shown in FIG. 12, which is based on the device 1 shown in FIG. 8. The free connection point 22 of the first radiation device 2 is electrically conductively connected to an antenna connection 4. The free connection point 21 of the second radiation device is electrically conductively connected to a ground connection 5. For the sake of clarity, the antenna 41 and grounding 51 connected to the connections 4 and 5 in practical use of the device 1 are indicated by dashed lines. This embodiment is also claimed in claim 3. All other embodiments of the device 1 shown in FIGS. 9 and 10 are electrically conductively connected to an antenna 4 and a ground connection 5 at their free connection points 21 and 22 in the sense of the above two exemplary embodiments. The two embodiments of claim 3 that are still missing can thus be realized.

If you swap antenna 4 and ground connection 5 in FIGS. 1 1 and 12, two of the embodiments claimed in claim 4 are obtained. The two remaining embodiments of claim 4 are realized by interchanging antenna 4 and ground connection 5 in the embodiments discussed in the previous section.

In a further advantageous embodiment of the device 1, two diodes 31 and 32 connected in series are inserted into the connecting line 3 of the above exemplary embodiments of claim 3, as shown in FIG. 13 for an exemplary embodiment of claim 3 according to FIG. 11, the ground connection is removed from the connection point 22 of the second radiation device 2 and is electrically conductively connected to the connection point 33. By varying the connecting line 3 according to the exemplary embodiments shown in FIGS. 8 to 10, all of the embodiments of the device 1 claimed in claim 5 can be realized.

FIG. 14 shows a further advantageous embodiment of the device 1, which is based on the exemplary embodiment shown in FIG. 13. In addition to the implementation shown in FIG. 13, a further antenna connection 5 is provided at the free connection point 22 of the implementation shown in FIG. 13. This embodiment of the device 1 and those embodiments which are obtained by adding an additional antenna connection 5 to the free connection point 21 or 22 of all the embodiments claimed in claim 4 and realized as described in the last paragraph are claimed in claim 6.

The devices 1 claimed in claims 7 and 8 can be realized by exchanging antenna connection / connections 4 and earth connection / connections 5 in the above-described embodiments of device 1 according to claims 5 and 6. FIG. 15 shows a further advantageous embodiment of the device according to the invention. Two opposing radiation devices 2 are connected in an electrically conductive manner between the connection points 21 via a first connecting line 3. They are also electrically conductively connected between the connection points 22 via a second connecting line 3. Two diodes 31 and 32 connected in series are inserted into both connecting lines 3 and are connected in an electrically conductive manner at connecting points 33. An antenna connection 4 is electrically conductively connected to the connection point 33 of the first connection line 3. A ground connection 5 is electrically conductively connected to the connection point 33 of the second connection line 3. This embodiment represents a realization of the device 1 claimed in claim 9, embodiment a).

By swapping antenna connection 4 and earth connection 5 in the previous exemplary embodiment, a practical implementation of the device 1 claimed in claim 9, embodiment b) is obtained.

A further advantageous embodiment of the device 1 according to the invention can be implemented as follows. Two opposing emitting devices 2 are electrically conductively connected via a first connecting line 3 between the connection point 21 of the first emitting device 2 and the connecting point 22 of the second emitting device 2. They are also electrically conductively connected between the connection point 22 of the first emitting device 2 and the connecting point 21 of the second emitting device 2 via a second connecting line 3. Two diodes 31 and 32 connected in series are inserted into both connecting lines 3 and are connected in an electrically conductive manner at connecting points 33. An antenna connection 4 is electrically conductively connected to the connection point 33 of the first connection line 3. A ground connection 5 is electrically conductively connected to the connection point 33 of the second connection line 3. This embodiment represents a realization of the device 1 claimed in claim 10, embodiment a).

By swapping antenna connection 4 and earth connection 5 in the previous exemplary embodiment, a practical implementation of the device 1 claimed in claim 10, embodiment b) is obtained. The diodes 31 and 32 inserted into the connecting line (s) 3 in claims 5 to 10 serve the purpose of avoiding undesired electrical vibrations of the device 1.

In a further advantageous embodiment of a device according to the invention for the compensation of electrosmog 1, the connection points 21 and 22 of the emitting devices 2 are designed such that they can be connected in an electrically conductive manner at least once. This embodiment represents a realization of the device 1 claimed in claim 11.

In a further advantageous embodiment of a device according to the invention for the compensation of electrosmog 1, the device 1 is designed as an encapsulated unit, from which solder, screw or plug connections 4 and 5 for an antenna 41 and a ground 51 are led out. This embodiment represents a realization of the device 1 claimed in claim 12.

In a further advantageous embodiment of a device according to the invention for the compensation of electrosmog 1, a diamagnetic metal, for example copper, is used for the metallic conductor 28 of the emitting devices 2 and a ferromagnetic metal, for example iron, is used for the metallic conductor 29 of the emitting devices 2. This embodiment represents a realization of the device 1 claimed in claim 13.

In a further advantageous embodiment of a device according to the invention for compensating for electrosmog 1, a diamagnetic metal, for example copper, is used for the metallic conductor 29 of the radiation devices 2 and a ferromagnetic metal, for example iron, is used for the metallic conductor 28 of the radiation devices 2. This embodiment represents a realization of the device 1 claimed in claim 14.

In a further advantageous embodiment of a device according to the invention for the compensation of electrosmog 1, the opposing radiation devices 2 are arranged side by side in the plane of a radiation device 2. This embodiment represents a realization of the device 1 claimed in claim 15. In a further advantageous embodiment of a device according to the invention for the compensation of electrosmog 1, the individual emitting devices 2 are arranged one behind the other in such a way that their planes lie essentially parallel to one another and that the points 25 and 26 of the first emitting device 2 lie essentially on one axis with the points 25 and 26 of the second radiation device 2. This embodiment represents a realization of the device 1 claimed in claim 16.

In a further advantageous embodiment of a device for compensating for electrosmog 1 according to the invention, a plurality of devices for compensating for electrosmog 1 according to the above exemplary embodiments are combined via a parallel connection to form a combination module 11. Parallel connection means that the antenna connections 4 of all devices for compensating for electrosmog 1 are connected to one another in an electrically conductive manner. With these connected antenna connections 4, the antenna 41 is connected in practical operation. The ground connections 5 of all devices for the compensation of electrosmog 1 are connected to one another in an electrically conductive manner. With these connected ground connections 5, the ground 51 is connected in practical operation. This embodiment represents a realization of the device 1 claimed in claim 17.

In a further advantageous embodiment of the device for compensating for electrosmog 1 according to the invention, a plurality 101 to 10 of devices 1 according to the above exemplary embodiments are combined into a combination module 11 via a series connection. Series connection means that in each case the antenna connection of a first device 101 is electrically conductively connected to the ground connection 5 of a second device 102, and so on until the desired total number n of devices 1 is connected, the ground 51 for the electrically conductive connection to the ground connection 5 the first device 101 is provided and the antenna 41 is provided for the electrically conductive connection to the antenna terminal 4 of the nth device 1 On. This embodiment represents a realization of the device 1 claimed in claim 18.

In practical use, the devices for compensating for electrosmog 1 according to the invention are arranged in the vicinity of an electrical device attached to it, for example pushed onto the neck of a picture tube of a monitor or attached to the rear wall of a plastic monitor housing, in particular on the inside thereof.

Claims

Name: Method and device for the compensation of electrosmog claims 1. A method for compensating for electrosmog, characterized in that a metallic structure in the form of a Möbius band, which forms a closed conductor loop, is used for transforming abiotic electromagnetic radiation into electromagnetic radiation with inverted Poynting vector P, in particular that the conductor loop consists of two different conductor pieces are preferably composed of the same length (Fig. 1). 2. Device for the compensation of electrosmog (1), consisting of: • A first electromagnetic radiation device (2), which consists of two metallic conductor pieces (28) and (29), which are connected at both ends at connection points (21) and (22) in an electrically conductive manner, preferably circular, this first radiation device (2) clockwise or essentially rotated to the left to the geometric shape of an eight, forming a first (23) and a second (24) conductor loop, the center of the first conductor loop (23) being defined by the point (25) and the center of the second conductor loop ( 24) is given by the points (26) and the first (23) and the second (24) conductor loop preferably comprise equal lengths of the metallic conductor pieces (28) and (29), the second conductor loop (24) of this first emitting device (2 ) is folded over so that it comes to lie on the first conductor loop (23) and that point (25) essentially coincides with point (26), • a second electromagnetic radiation device (2), which consists of two metallic conductor pieces (28) and (29), which are connected at both ends at connection points (21) and (22) in an electrically conductive manner, preferably circular, this second radiation device (2) in In the case of a right-handed first emitting device (2) left-handed or in the case of a left-handed first emitting device (2) essentially right-handed is twisted to the geometrical shape of an eight, forming a first (23) and a second (24) conductor loop, the center of the first conductor loop (23) through the point (25) and the center of the second conductor loop (24) through the Points (26) are given and the first (23) and the second (24) conductor loop preferably comprise the same lengths of the metallic conductor pieces (28) and (29), the second conductor loop (24) of this second emitting device (2) being folded over in this way that it comes to rest on the first conductor loop (23) and that point (25) essentially coincides with point (26), • a connecting line (3) which a) receives the first emitting device (2) electrically connecting their connection point (21) to the connection point (21) of the second emitting device (2) or b) connecting the first emitting device (2) at their connecting point (21) to the connecting point (22) of the second emitting device (2 ) electrically conductively connects or c) connects the first radiation device (2) at its connection point (22) to the connection point (21) of the second radiation device (2) in an electrically conductive manner or d) connects the first radiation device (2) at its connection point (22) connects the connection point (22) of the second emitting device (2) in an electrically conductive manner. 3. A device for compensation of electrosmog (1) according to claim 2, characterized in that the still free connection point (22) or (21) of the first radiation device (2) with an antenna connection (4) is electrically connected and the still free connection point (22) or (21) of the second radiation device (2) with an earth connection (5) is electrically conductively connected. 4. A device for compensation of electrosmog (1) according to claim 2, characterized in that the still free connection point (22) or (21) of the first emitting device (2) with an earth connection (5) is electrically connected and the still free connection point (22) or (21) of the second radiation device (2) is electrically conductively connected to an antenna connection (4). 5. A device for compensating for electrosmog (1) according to claim 2, characterized in that in the connecting line (3) two series connected diodes (31) and (32) are inserted, which are electrically conductive with each other at a connection point (33) are connected such that the still free connection point (22) or (21) of the first emitting device (2) is electrically conductively connected to an antenna connection (4) and the connection point (33) is electrically conductively connected to a ground connection (5). 6. A device for compensating for electrosmog (1) according to claim 5, characterized in that the still free connection point (22) or (21) of the second radiation device (2) is electrically conductively connected to a further antenna connection (4). 7. The device for compensating for electrosmog (1) according to claim 2, characterized in that in the connecting line (3) two series-connected diodes (31) and (32) are inserted, which are electrically conductively connected to one another at a connecting point (33) are that the still free connection point (22) or (21) of the first radiation device (2) is electrically conductively connected to a ground connection (5) and the connection point (33) is electrically conductively connected to an antenna connection (4). 8. A device for compensating for electrosmog (1) according to claim 7, characterized in that the still free connection point (22) or (21) of the second radiation device (2) is electrically conductively connected to a further ground connection (5). 9. Device for the compensation of electrosmog (1), consisting of: • A first electromagnetic radiation device (2), which consists of two metallic conductor pieces (28) and (29), which are connected at both ends at connection points (21) and (22) in an electrically conductive manner, preferably circular, this first radiation device (2) clockwise or essentially rotated to the left to the geometric shape of an eight, forming a first (23) and a second (24) conductor loop, the center of the first conductor loop (23) being defined by the point (25) and the center of the second conductor loop ( 24) is given by the points (26) and the first (23) and the second (24) conductor loop preferably comprise equal lengths of the metallic conductor pieces (28) and (29), the second conductor loop (24) of this first emitting device (2 ) is folded over so that it comes to lie on the first conductor loop (23) and that point (25) essentially coincides with point (26), • a second electromagnetic radiation device (2), which consists of two metallic conductor pieces (28) and (29), which are connected at both ends at connection points (21) and (22) in an electrically conductive manner, preferably circular, this second radiation device (2) in In the case of a clockwise first emitting device (2) counterclockwise or in the case of a counterclockwise first emitting device (2) clockwise, essentially twisted to the geometric shape of an eight, each forming a first (23) and a second (24) conductor loop, the center of the the first conductor loop (23) is given by the point (25) and the center of the second conductor loop (24) is given by the points (26) and the first (23) and the second (24) conductor loop are preferably equal lengths of the metallic conductor pieces (28) and (29), wherein the second conductor loop (24) of this second emitting device (2) is folded over so that it is so on the first Le it loop (23) comes to rest and that point (25) essentially coincides with point (26), • a first connecting line (3), which connects the first emitting device (2) at its connecting point (21) with the connecting point (21) of the second emitting device (2) in an electrically conductive manner, in which connecting line (3) two diodes connected in series (31) and (32) are inserted, which are electrically conductively connected to one another at a connection point (33), • a second connecting line (3), which connects the first emitting device (2) at its connecting point (22) with the connecting point (22) of the second emitting device (2) in an electrically conductive manner, in which second connecting line (3) two diodes connected in series (31) and (32) are inserted, which are electrically conductively connected to one another at the connection point (33), • a) an antenna connection (4) which is electrically conductively connected to the connection point (33) of the first connection line (3) or b) an antenna connection (4) which is electrically conductive to the connection point (33) of the second connection line (3) is connected, and • in the above case a) a ground connection (5) which is electrically conductively connected to the connection point (33) of the second connecting line (3) or in the above case b) a ground connection (5) which is connected to the connection point (33) of the first Connection line (3) is electrically conductively connected. ION device for the compensation of electrosmog (1), consisting of: • A first electromagnetic radiation device (2), which consists of two metallic conductor pieces (28) and (29), which are connected at both ends at connection points (21) and (22) in an electrically conductive manner, preferably circular, this first radiation device (2) clockwise or essentially rotated to the left to the geometric shape of an eight, forming a first (23) and a second (24) conductor loop, the center of the first conductor loop (23) being defined by the point (25) and the center of the second conductor loop ( 24) is given by the points (26) and the first (23) and the second (24) conductor loop preferably comprise equal lengths of the metallic conductor pieces (28) and (29), the second conductor loop (24) of this first emitting device (2 ) is folded over so that it comes to lie on the first conductor loop (23) and that point (25) essentially coincides with point (26), • a second electromagnetic radiation device (2), which consists of two metallic conductor pieces (28) and (29), which are connected at both ends at connection points (21) and (22) in an electrically conductive manner, preferably circular, this second radiation device (2) in In the case of a clockwise first emitting device (2) counterclockwise or in the case of a counterclockwise first emitting device (2) clockwise, essentially twisted to the geometric shape of an eight, each forming a first (23) and a second (24) conductor loop, the center of the the first conductor loop (23) is given by the point (25) and the center of the second conductor loop (24) is given by the points (26) and the first (23) and the second (24) conductor loop are preferably equal lengths of the metallic conductor pieces (28) and (29), wherein the second conductor loop (24) of this second emitting device (2) is folded over so that it is so on the first Le it loop (23) comes to rest and that point (25) essentially coincides with point (26), • a first connecting line (3) which connects the first emitting device (2) at its connecting point (21) to the connecting point (22) of the second emitting device (2) in an electrically conductive manner, two connecting diodes (3) connected in series in this connecting line (3) 31) and (32) are inserted, which are connected to one another in an electrically conductive manner at a connection point (33), • a second connecting line (3), which connects the first emitting device (2) at its connecting point (22) to the connecting point (21) of the second emitting device (2) in an electrically conductive manner, with two connecting lines (3) in series in this second connecting line switched diodes (31) and (32) are inserted, which are electrically conductively connected to one another at the connection point (33), and • a) an antenna connection (4) which is electrically connected to the connection point (33) of the first connection line (3) or b) an antenna connection (4) which is electrically connected to the connection point (33) of the second connection line (3) . • in the above case a) a ground connection (5) which is electrically connected to the connection point (33) of the second connection line (3) or in the above case b) an earth connection (5) which is connected to the connection point (33) of the first connection line (3) is electrically connected. 11.Device for the compensation of electrosmog (1) according to one of claims 2 to 10, characterized in that the connection points (21) and (22) of the emitting devices (2) are designed to be pluggable in such a way that they can be electrically conductively connected at least once . Device for the compensation of electrosmog (1) according to one of claims 2 to 10, characterized in that the device (1) as an encapsulated unit with solder, plug or screw connections (4) and (5) for an antenna (41) and earthing (51) is carried out. 13.Device for the compensation of electrosmog (1) according to one of claims 2 to 10, characterized in that the metallic conductor piece (28) consists of a diamagnetic metal, in particular copper, and the metallic conductor piece (29) made of a ferromagnetic metal, in particular Iron exists. Device for the compensation of electrosmog (1) according to one of Claims 2 to 10, characterized in that the metallic conductor piece (29) consists of a diamagnetic metal, in particular copper, and the metallic conductor piece (28) consists of a ferromagnetic metal, in particular iron . 15Device for compensating for electrosmog (1) according to one of Claims 2 to 10, characterized in that the conductor loops (23) and (24) of the individual emitting devices (2) are arranged essentially in one plane. 16The device for compensating for electrosmog (1) according to one of Claims 2 to 10, characterized in that the individual emitting devices (2) are arranged one behind the other in such a way that their conductor loops (23) and (24) lie essentially parallel to one another and that the points (25) and (26) of the first emitting device (2) lie essentially on one axis with the points (25) and (26) of the second emitting device (2). 17. Combination module (11) for the compensation of electrosmog, consisting of n devices for the compensation of electrosmog (101) to (lOn) according to one of claims 2 to 10, characterized in that the individual devices (101) to (lOn) in one Parallel connection are electrically conductively connected to one another in such a way that the antenna connections (4) of all devices (101) to (10n) are electrically conductively connected to one another such that these connected antenna connections can serve for the electrically conductive connection of an antenna (41) such that the earth connections (5 ) of all devices (101) to (10n) are connected to one another in an electrically conductive manner and that these connected earth connections (5) can serve for the electrically conductive connection of an earth connection (51). 1 δ.Kombinationsmodul (11) for compensating for electrosmog, consisting of at least two devices for compensating for electrosmog (101) and (102) according to one of claims 2 to 10, characterized in that the individual devices (1) in a series circuit with each other are connected, ie that the ground connection (5) of the device (101) serves for the electrically conductive connection of a ground (51), that the antenna connection (4) of a first device (101) is electrically conductively connected to the ground connection (5) of a second device (102) , The antenna connection (4) of the second device (102) for the electrically conductive connection of an antenna (41) or for the electrically conductive connection with further devices (103) to (10n) in the example of the devices (101) and (102) specified manner, wherein in the latter case the antenna connection (4) of the nth device (10n) is used for the electrically conductive connection of an antenna (41).