AT503481A1 - METHOD FOR GENERATING A GRAVITATION FIELD AND GRAVITATION FIELD GENERATOR - Google Patents

Description

The invention relates to a method and an arrangement for generating a gravitational field or a gravitational field generator.

In a first approximation Einstein's equations of general relativity describe a Maxwell-like structure of the gravitational field. This means that in addition to Newton's gravitational field g there is a so-called gravitomagnetic field Bg. Both fields are linked by an induction equation, similar to the electromagnetic fields.

In practice, gravitomagnetic fields and their induction equation are of no importance, since these fields are so small that they can only be measured with the aid of complex space satellites. In De Matos, C.J., and Tajmar, M., " Gravitomagnetic London Moment and the Graviton Mass inside a Superconductor ", Physica C, Vol, 432, 2005, pp. 167-172, in Tajmar, M. and De Matos, C.J., " Extended Analysis of Gravitomagnetic Fields in Rotating Superconductors and Superfluids ", Physica C, Vol. 420, No, 1.2, 2005, pp. 56-60, as well as Tajmar, M., and De Matos, C.J., " Gravitomagnetic Field of a Rotating Superconductor and of a Rotating Superfluid ", Physica C, Vol. 385, no. 4, 2003, pp. 551-554, it has been shown that matter is in a coherent state (boson particles that obey the Bose-Einstein statistic), e.g. As superconductors, superfluids, or Bose-Einstein condensates, they can generate gravitomagnetic fields much larger than those of normal matter. The special thing about a superconductor is, among other things, that its canonical moment is quantized. In a superconductor, which is much thicker than the London penetration depth (typically 100 nm), there is a clear correlation between the mechanical, electromagnetic and gravitomagnetic moment. When you rotate the superconductor, it creates a magnetic and gravitomagnetic field to hold its canonical moment. The strength of the gravitomagnetic field depends on the density of the coherent medium, in the case of the superconductor this is the Cooper pair density, in relation to the density of the material used. In the case of a niobium superconductor, the gravitomagnetic field Bg is "10" 5-ö > rad.s'1, where ω is the rotation frequency. Fig. 1 shows a superconducting ring 1, which generates a gravitomagnetic field Bg in rotation about an axis of rotation A.

The aim of this invention is the creation of a method or an arrangement, in particular a gravitational field generator, with which a constant (or quasi-stationary) or temporally variable acceleration field, or by the equivalence principle veraligemeint, a gravitational field can be generated which allows technical applications. • · • · • ··

An arrangement for generating an applicable gravitational field, i. a gravitational field generator, is illustrated in FIG. A superconductor 1 rotates at the frequency goi about its axis A to generate a gravitomagnetic field. The axis 1 is tangent to the orbit. In addition, the rotating superconductor 1 rotates at a frequency ü> 2 around a center R, as shown in Fig. 2, and forms a torus through its orbit. This arrangement produces a gravitational field g as shown, with constant rotation. The rotations can be made by means of any drives, e.g. an engine, but also by means of gas streams or electromagnetic fields. The strength of the gravitational field g can be increased by increasing the number of superconductors 1 rotating about the axis A at the rotational speed ωι and rotating about the rotational axis R at the same rotational speed ω2. In this embodiment, the gravitational field above and below the superconductor is strongest and points in the direction of rotation about the axis R. By the rotation of the superconductor, the gravitational field is pulsed but constant in its direction.

A stronger field can be achieved with an array or a gravitational field generator, as shown in FIG. The first axis of rotation A is perpendicular to the second axis of rotation R and lies in the orbital plane. In this way a unidirectional, nearly homogeneous gravitational field can be created. Exactly in the rotation axis R, the gravitational field is also constant in time, only outside the axis R it is pulsed.

Another variant is shown in FIG. 4. The axis A is parallel to the axis of rotation R and is perpendicular to the plane of rotation. In this arrangement, a gravitational field above and below the superconductor is generated, which is also on the rotation axis R temporally stable and off the axis A pulsed. The great advantage of this variant is that the load on the bearings in the axis A, which are required for the rotation of the superconductor, is minimal in comparison to FIGS. 2 and 3. However, the gravitational field in the middle is thinner than in FIG. third

In general, it is advantageous to always operate the superconductors in pairs in order to minimize imbalance forces, whereby the orientation of the superconductors of the respective pair must be taken into account. The more superconductors are rotated about the axis R, the stronger and more homogeneous the gravitational field. In general, the vector ω1 can be arbitrary to the vector ω2, then there is a hybrid between the cases outlined in Fig. 2-4, where the vectors a> i are perpendicular to each other and each perpendicular to ω2.

In order to concentrate the gravitational field into another sector, an arrangement or a gravitational field generator, as shown in plan view in FIG. 5, can be used with four superconductors 1. In principle, any number of superconductors rotating around their first rotation axis A with g> i can be rotated in a star-shaped arrangement around the center or the rotation axis R with α> 2.

In addition, over a section, e.g. along the half, of the circulating circuit a magnetic field 2 are formed, e.g. by a permanent magnet having a semicircular pole piece. The magnetic field established by the magnet is greater than the critical magnetic field of the individual superconductors, so that the magnetic field terminates the superconducting state upon entry of the respective superconductor 1 into the magnetic field and collapses the gravitational field. After leaving the area of influence of the magnetic field 2, the respective superconductor resumes its superconducting state. This symmetry break produces a gravitational field g, as shown in Fig. 4, which is normal to the drawing plane and now concentrated outside the center in the sector opposite to the magnetic field.

An advantageous embodiment is shown in Fig. 6. A Kyrostat 3 is filled with liquid helium or nitrogen 4 (depending on whether a high temperature or a classical superconductor is used), which is evaporated to cool the superconductors to the required temperature. The superconductors 1 are rotated by applying a rotating field to coils 5 about the first axis of rotation A. By additional electromagnetic fields, alternatively, a motor can be used in each case, the superconductors 1 are rotated in the Kyrostaten 3 about the second axis of rotation R with ω2. In the recess 6 creates a gravitational field g, which can be used practically.

The strength of this gravitational field is directly proportional to the product gm · ω2. For a niobium superconductor torus with a diameter of one meter would have the product of the rotational speeds ω! and ω2 are about 10,000 RPM in order to reach the strength of the gravitational field of the earth.

By changing a direction of rotation, the gravitational field inside can also be reversed.

If the recess 6 is large enough, one could create a homogeneous gravitational field that is opposite to the earth gravitational field, thus simulating a weightless state of lesser gravity.

If (Di and / or ω2 and / or the magnetic field 2 are not constant, a time-varying gravitational field is created.) Such a field can be used for communication purposes, for example.

An arrangement for generating a variable gravitational field is shown in FIG. 7. A superconductor 1, optionally in a cryostat with appropriate cooling, is rotated with coi, comprising a constant and a variable portion. The variable component can be similar to a frequency modulation in the

Communication with electromagnetic waves are used. Depending on the variable component, the gravitational field changes. The thus formed gravitational wave can be recorded by means of an acceleration sensor 7 and transformed into electrical signals. The advantage of this method is that the gravitational wave, unlike electromagnetic waves, penetrates unhindered every obstacle 8.

The arrangement according to FIG. 7 can be supplemented with a unit for establishing a variable magnetic field. The magnetic field is used to modulate the superconducting state of the body when the magnetic field exceeds or falls below the critical magnetic field of the superconductor so that gravitational waves are transmitted. In this case, the superconductor can also be rotated at a constant rotation speed <Bi around its rotation axis A, which simplifies the arrangement. A rotation about a second axis of rotation is not required.

A gravitational field generator as shown in Figures 2 to 6 comprises doubly rotating coherent matter (e.g., a superconductor) and creates a gravitational field inside the orbit. This gravitational field can be either stationary or variable in time, its polarity depends on the sense of rotation of the superconductor. This gravitational field can be used to move any kind of matter. For example, it is possible to build a shield that repels matter. It is also conceivable that such a generator is used to compensate for centrifugal forces or to generate an earth-like gravitational field in a space station or spaceship.

Furthermore, the gravitational field generator can be used to generate gravitational waves, which can be used for communication as shown in FIG.

The material of the coherent matter enters into the strength of the generated gravitational field over the density of the coherent state to the normal matter density (ie Cooper pair mass density to normal material density in the superconductor). There are arbitrarily shaped body can be used, which are displaceable in a coherent state. Such coherent bodies may be in the form of thin layers deposited on carriers. The coherent bodies can be made of metallic or non-metallic or semi-metallic compounds. The transition temperature of the coherent bodies does not matter. The coherent bodies may consist wholly or partly of superconducting compounds or substances, the size of the coherent bodies is selectable. For the strength of the generated gravitational field, the product of the rotational speed ω 1 of the first rotation and the rotational speed ω 2 of the second rotation are primarily decisive.

The directions of the rotation axis A with respect to the rotation axis R shown in the figures are advantageous; a deviation from these directions is possible without further.

Claims (17)

Claims: 1. A method of generating a gravitational field, characterized by &gt; in that at least one body in coherent, superconducting state is rotated about a first axis of rotation passing through its body, and - that said rotating coherent / superconducting body is additionally rotated about a second axis of rotation, preferably located outside its body. 2. The method according to claim 1, characterized in that during the rotation of the body about the second axis of rotation at least over a predetermined portion of this orbit of the body with a, in particular stationary, magnetic field is applied, which exceeds the critical magnetic field of the body and with this magnetic field the body is placed in the normal conducting state via this section of the orbit from the coherent / superconducting state. 3. The method according to claim 2, characterized in that the predetermined portion of the rotational path over which the coherent body is placed in a normally conductive state, is about half the circumference of the rotational path. 4. The method according to any one of claims 1 to 3, characterized in that by specifying the rotational speeds (ωι, ω2), with which the body is rotated about the first and second axes of rotation, the strength of the gravitational field is adjusted and that optionally the product of Speeds with which the body is rotated about the first axis of rotation or the body is rotated about the second axis of rotation, in particular to achieve a gravitational field, which corresponds approximately to the gravitational acceleration, chosen at a diameter of the orbit of about 1m at 8,000 to 12,000 revolutions / min becomes. 5. The method according to any one of claims 1 to 4, characterized in that the first axis of rotation (A) perpendicular to the second axis of rotation R is established. 6. The method according to any one of claims 1 to 5, characterized in that the first axis of rotation (A) is set up either tangentially to the by the rotation about the second axis of rotation (R) certain orbit perpendicular to this orbit or perpendicular to the orbital plane. 7. Arrangement for generating a gravitational field or gravitational field generator, in particular for carrying out the method according to one of claims 1 to 6, characterized in that the arrangement or the gravitational field generator comprises at least one coherent / superconducting body (1) having a first rotary drive (5) is driven in rotation about a rotation axis (A) extending in particular through its body or enclosed by it, and that a further rotary drive is provided, with which the rotating coherent / superconducting body (1) and the first rotary drive around one, in particular outside the body, the second axis of rotation (R) are set in rotation. 8. Arrangement according to claim 7, characterized in that as rotary drives (5) electric motors, rotating fields generating electric coils, rotations of the body causing gas flows are provided, which optionally also support the coherent body in the course of its rotational movement about the first and / or second axis of rotation , 9. Arrangement according to claim 7 or 8, characterized in that in the around the second axis of rotation (R) extending orbit a plurality of coherent / superconducting bodies (1), in particular at equal angular intervals, is arranged. 10. Arrangement according to one of claims 7 to 9, characterized in that the body (1) is rotationally symmetrical at least with respect to an axis of symmetry extending through the body. 11. Arrangement according to one of claims 7 to 10, characterized in that the body (1) is rotated about an axis of symmetry. 12. Arrangement according to one of claims 7 to 11, characterized in that the body (1) has ball, ring or disc shape. 13. Arrangement according to one of claims 7 to 12, characterized in that in the arrangement of a plurality of coherent / superconducting bodies (1) in the orbit about the second axis of rotation (R) all bodies (1) rotate in the same direction around the orbit or the first axis of rotation (A) tangent to the orbit. • ···· <t · Η ··· ι · · · ························································································ ··· ·· ·· · 14. Arrangement according to one of claims 7 to 13, characterized in that the first axis of rotation (A) of the coherent / superconducting body (1) is located in the orbit plane of the orbit and is perpendicular to the orbit. 15. Arrangement according to one of claims 7 to 14, characterized in that during the rotation of the body (1) about the second axis of rotation (R) at least over a predetermined portion of this orbit of the body with a, in particular stationary, magnetic field is applied, the exceeds the critical magnetic field of the body and is placed with this magnetic field of the body over this portion of the orbit from the coherent / superconducting state in a normal conducting state. 16. Arrangement, in particular according to one of claims 7 to 15, characterized in that - at least one body (1) is rotated in coherent / superconducting state about a running through his body or by this enclosed first axis of rotation (A), and - in that the body is arranged in the sphere of influence of a magnet with which a variable magnetic field which exceeds the critical magnetic field of the superconductor at predetermined times and / or for predetermined periods of time is dispensable. 17. Arrangement according to claim 16, characterized in that a unit for changing the magnetic field of the magnet is provided, e.g. a switching unit for switching the coil current of an electromagnet. Vienna, am