The present invention relates in general, to the field of aviation and to a device for propulsion generation for objects flying in air and airless environment, without the use of a jet engine.
Since the invention of jet engines, no new engines have emerged that are capable of ensuring the movement of a flying objects in an airless environment. This is mainly due to the traditional ban on such movement, imposed by the third law of Newton—the law of conservation of mechanical momentum. However, a more general law of conservation of momentum asserts the constancy of the sum of all the momentums of the system, and this sum include an electromagnetic momentum. This violates Newton's third law, which is equivalent to the law of conservation of a mechanical momentum.
New propulsion devices that have been suggested before, as far as we know, were not implemented. U.S. Pat. No. 1,974,483 “Electrostatic motor” describes a motor based on Biefeld-Brown effect, an effect that has not received a generally accepted explanation to this date.
U.S. Pat. No. 3,120,363, “Flying apparatus” describes a propulsion device based on ion discharge. However, this device cannot operate in the absence of atmosphere.
Russian PatentRU-2172865 “Method of obtaining tractive effort” proposes a method for “ensuring the translational movement of transport, including space vehicles.” However, the author himself points out that, in accordance with his theory, the tractive force in the proposed constructions will be very small
Israel Patent 200435 by S. Khmelnik “A capacitor engine for an aircraft” describes a device intended for flights in an airless environment. It also implements the Biefeld-Brown effect. The disadvantage of this device is the complexity of the design and the need for a high-voltage generator
UK Patent GB 2537119, “Superconducting microwave radiation thruster” describes a system designed for flights in space. This system clearly demonstrates the creation of tractive force due to electrodynamic effects. The disadvantage of this device is an extremely small amount of driving force.
Hence there is a need for high thrust propulsion device that can operate in airless environment.
Described hereafter is a device for the conversion of electromagnetic momentum into propulsion mechanical momentum. The device is built from rotating disk, made of non-magnetic material, on the circumference of which plurality of bar magnets are mounted. The bar magnets are in a plane which is perpendicular to the plane of the disk and in a plane which is perpendicular to the radius of the disk that meets the centre of the bar magnet. The disk is driven by a motor that causes it to rotate. The magnets are positioned in an angle, called the shift angle, relative to the rotation axis of the disk. When the disk rotates, mechanical momentum, perpendicular to the plane of the rotating disk is generated. This momentum acts on the disk and causes it to move along the axis of rotation of the disk.
The electromagnetic momentum is generated by the change in the magnetic flux—due to the movements of the magnets. This electromagnetic momentum, in accordance with the law of conservation of momentum appears as a mechanical momentum acting on the device.
There are many configurations for implementing the invention, and a skilled man in the art can select a desired configuration.
It is an objective of the present invention to provide a device for generation of propulsion in airless environment without the use of rocket engines.
Described hereafter is a device for the conversion of electromagnetic momentum into propulsion mechanical momentum in airless environment. The device is comprised of a disk made of non-magnetic material rotated by a motor. The motor gets its energy from a source, such as electric battery. On the circumference of the disk plurality of bar magnets are mounted. The bar magnets are in a plane which is perpendicular to the plane of the disk and in a plane, which is perpendicular to the radius of the disk that meets the centre of the bar magnet. The magnets are positioned in an angle, called the shift angle, relative to the rotation axis of the disk. When the disk rotates, mechanical momentum, perpendicular to the plane of the rotating disk is generated. This momentum acts on the disk and causes it to move along the axis of rotation of the disk.
The electromagnetic momentum is generated by the change in the magnetic flux—due to the movements of the magnets. This electromagnetic momentum, in accordance with the law of conservation of momentum appears as a mechanical momentum acting on the device.
There are many configurations for implementing the invention, and a skilled man in the art can select a desired configuration.
The invention will be described more fully hereinafter, with reference to the accompanying drawings, in which certain possible embodiments of the invention are shown. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather these embodiments are provided so that the disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art.
A general structure of an embodiment of the device is shown in
A top view of the device is presented in
Explanation of the principle of operation of the device follows. The explanation refers to
E=V×B (1)
The magnetic induction B is aligned with the magnetic intensity H-208, and are related by the formula (2):
B=μ·H where μ is the magnetic permeability. (2)
The vector of the flux density of electromagnetic energy S is given by the following vector product equation:
S=E×H (3)
S=μ(V×H)×H (4)
The components of the S, V and H vectors are S=[Sx, Sy, Sz]; V=[Vx, Vy, Vz] and H=[Hx, Hy, Hz], and noting that Vx=Vz=0 and Hz=0, and Hx=|H| cos α; Hy=|H| sin α we can write (4) as follows:
The density of magnetic energy is given by:
Note that equation (8) refers only to one end of the bar magnet. When the two magnet ends are taken into consideration, we get that the flux density of electromagnetic energy for the bar magnet Sm equals two times that of one side, i.e. Sm=2S, as shown in
Sm=4·|V|·Wm·Q (9)
There is the idea in physics of motion of energy, the flow of energy and the velocity of energy motion. In our case the energy flux density s, the energy density w and the energy velocity v are related by the formula:
S=w*v (10)
It is known that in electromagnetic fields the velocity of energy motion is much less than the velocity of light. In our case, together with the magnet, the electromagnetic energy stored in it is transferred. The motion of this energy also creates a stream of electromagnetic energy, discussed above. This energy moves at a certain velocity Vs. In our case, formula (9) takes the form:
Sm=Wm*Vs (11)
Comparing equations (9) and (11) we get that
Vs=4·|V|·Q (12)
So that Vs has two components, one directed along YL axis and the other along the XL axis.
It is known that the electromagnetic fields in which electromagnetic energy flow exists, also contain fluxes of the electromagnetic momentum, and the electromagnetic momentum and the mechanical momentum enter the law of conservation of momentum in an equal manner. At the same time, the density of the electromagnetic momentum J and the flux density of an electromagnetic energy Sm are related by a relation having the form:
Combining (11) and (13) we can write:
J=Wm/Vs=Wm/(|V|·4·Q) (14)
We can define Q′=1/(4·Q)={0.5/(sin (2α)), −1/(4 cos2(α)), 0}
J=[Wm/(|V|)]·Q′) (15)
The density vector of the electromagnetic momentum is directed in the same way as the vector of the flux density of the electromagnetic energy. In accordance with the law of conservation of momentum, the electromagnetic momentum, together with the mechanical momentum of the magnet must be zero, since at the beginning of the motion the latter was absent. Consequently, the body of the magnet acquires a mechanical momentum.
As noted earlier, the magnets on the disk can be arranged in many different configurations. One such configuration is shown in
In another embodiment a control unit is added, where it can control the speed of the motor. In another embodiment a control unit can control the shift angle which is the angle between the bar magnet and the XL axis so control the propulsion.
What has been described above are just a few possible embodiments of the disclosed invention. It is of course, not possible to describe every conceivable combination of components and/or methodology, but one of ordinary skill in the art may recognize that many further combinations and permutations are possible. Accordingly, the invention is intended to embrace all such alterations, modifications, and variations that fall within the spirit and scope of the invention.
This application claims the benefit of U.S. Provisional Patent Application 62/621,054 filed on Jan. 24, 2018, which is incorporated herein by reference.
Filing Document | Filing Date | Country | Kind |
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PCT/IL2019/050084 | 1/22/2019 | WO | 00 |
Number | Date | Country | |
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62621054 | Jan 2018 | US |