Pulsed Electromagnetic Propulsion System

Abstract

The present invention discloses propulsion system operating exclusively in electromagnetic domain. Only electromagnetic field and direct electric current are used to generate propulsion force. In exemplary embodiment two switchable electromagnets, one to generate electromagnetic field, the other to generate electromagnetic force are used. To disable electromagnetic reaction force on electromagnetic field generator, streams of independent but synchronized direct current pulses passing through two electromagnets are organized in the way that first electromagnet is always carrying current when magnetic field generated by second electromagnet reaches it, thus generating Laplace force, whereas, second electromagnet is never carrying current (open circuit) when magnetic field generated by the first electromagnet reaches it, which means, no Laplace reaction force ever occurs on second electromagnet. The system therefore does not depend on the emission of matter. Only electric current is needed.

Claims

1. Pulsed Electromagnetic Propulsion System comprising: at least two electromagnetic field sources fixed to a common frame and separated by a predetermined distance; at least one electromagnetic field source with its own power source, as an active electromagnetic field source; one direct current source connected to each and every active electromagnetic field source through programmable electronic switch; a time management for programmable electronic switches designed to send direct current pulses to active electromagnetic field sources in order to preserve electromagnetic force acting on one electromagnetic source while disabling reactive electromagnetic force acting on other electromagnetic source.

2. Pulsed Electromagnetic Propulsion System of claim 1, wherein electromagnetic field sources placing and orientation are axial in order to enable electromagnetic force interaction between them.

3. Pulsed Electromagnetic Propulsion System of claim 1, wherein the distance between electromagnetic field sources is large enough to allow switching transient phenomena to stabilize, which means static electromagnetic field generated by direct current to form.

4. Pulsed Electromagnetic Propulsion System of claim 1, wherein electromagnetic field source is a conductor of any shape powered by current source, which means it is an active electromagnetic field source.

5. Pulsed Electromagnetic Propulsion System of claim 1, wherein electromagnetic field source is a coil of any shape made of conductor powered by current source, which means it is an active electromagnetic field source.

6. Pulsed Electromagnetic Propulsion System of claim 5, wherein a coil being one turn of wire-conductor, the coil being round, rectangular or any shape.

7. Pulsed Electromagnetic Propulsion System of claim 1, wherein electromagnetic field source is a short-circuited coil, which means it is a passive electromagnetic field source.

8. Pulsed Electromagnetic Propulsion System of claim 7, wherein a coil being one turn of wire-conductor, the coil being, round, rectangular or any shape.

9. Pulsed Electromagnetic Propulsion System of claim 1, wherein electromagnetic field source is a core made of soft ferromagnetic material, which means it is a passive electromagnetic field source.

10. Pulsed Electromagnetic Propulsion System of claim 1, wherein electromagnetic field sources and electronic switches are nanoscale structures fabricated on a silicon chip.

11. Pulsed Electromagnetic Propulsion System of claim 1, wherein multiple small electromagnetic field sources operate in parallel in order to substantially increase electromagnetic force.

12. Pulsed Electromagnetic Propulsion System of claim 1, wherein the distance between electromagnetic field sources is larger than the length of current conductor in individual electromagnetic sources in order to prevent time overlapping with the time management.

13. Pulsed Electromagnetic Propulsion System of claim 1, wherein time management for programmable electronic switches manages current pulses in a way that the first electromagnet is always carrying current when magnetic field generated by the second electromagnet reaches first electromagnet thus generating Laplace force, whereas the second electromagnet is never carrying current (open circuit) when magnetic field generated by the first electromagnet reaches second electromagnet, which means no Laplace reaction force ever occurs on second electromagnet.

14. Pulsed Electromagnetic Propulsion System of claim 1, wherein individual direct current pulses last twice the time the electromagnetic field needs to travel the distance between electromagnetic field sources.

15. Pulsed Electromagnetic Propulsion System of claim 7, wherein time management for programmable electronic switch manages current pulses in the way that first electromagnet is never carrying current when magnetic field generated by passive second electromagnetic field source, short-circuited coil, reaches first electromagnet therefore never generating Laplace force on the first active electromagnet, whereas, second, passive electromagnetic field source is generating electromagnetic force while activated-polarized when magnetic field generated by first electromagnet reaches it.

16. Pulsed Electromagnetic Propulsion System of claim 9, wherein time management for programmable electronic switches manages current pulses in the way that first electromagnet is never carrying current when magnetic field generated by passive second electromagnetic source, soft ferromagnetic core, reaches first electromagnet therefore never generating Laplace force on the first active electromagnet, whereas, second, passive electromagnetic source-ferromagnetic core is generating electromagnetic force while activated-polarized when magnetic field generated by first electromagnet reaches it.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0009] FIG. 1 shows basic hardware described in exemplary embodiment, two coils-electromagnets fixed on common frame and both coils connected to direct current sources through programmable electronic switches.

[0010] FIG. 2 shows timing diagram, as described in exemplary embodiment, of two cycles of direct current pulses applied to each electromagnet as well as electromagnetic forces acting on them, all synchronized to a common clock.

DETAILED DESCRIPTION OF THE INVENTION

[0011] Science behind this invention is based on a definition of electromagnetic force field as a non-contact force acting anywhere in a field. Electromagnetic force field can also be viewed as a quantum field with photons as force carriers which is important for this invention because photons travel at speed of light meaning that electromagnetic interaction is not instantaneous, this being underlying property that makes this invention possible.

[0012] Practical idea of how this invention works is to initiate electromagnetic force interaction between a minimum of two distinctly separated controllable-switchable electromagnetic field sources attached to a common frame and to interfere with their electromagnetic force interaction by switching individual electromagnetic fields on and off in the way that electromagnetic force on one source is preserved whereas the electromagnetic force on the other is disabled. To keep electromagnetic force unidirectional as desired, direct current pulses are used in order to generate magnetic fields that do not change its direction.

[0013] Exemplary embodiment of the invention (see FIG. 1) comprises two distinctly separated electromagnets 100 and 102 mechanically coupled to a common frame 104 and axially aligned in order to enable maximum electromagnetic force interaction between them. Each electromagnet is connected to a direct current source 106, 110 through programmable electronic switches 108, 112. Both switches are controlled independently by common programmable control unit (not shown).

[0014] Distance d between the two coils tells us how much time electromagnetic wave needs to travel between the two electromagnets Td=d/c (c is speed of light). That time enables us to use electronic switches to control direct current pulses through two electromagnets in the way that the first electromagnet 100 is always carrying current (switch 108 closed) when reached by the magnetic field generated by the second electromagnet 102 thus generating Laplace force (propulsion), while the second electromagnet 102 is never carrying current (switch 112 open) when reached by the magnetic field generated by the first electromagnet 100 meaning that there is no Laplace reaction force on second electromagnet 102.

[0015] Process can be reversed if we want active force on second electromagnet 102 and no force on first electromagnet 100.

[0016] Transient phenomena which occur at moments when switches turn on and off are related to physical dimensions, geometry and inductance (length of the conductor) of the coils which are part of used electromagnets and to electrical properties of current sources and switches. Only after the transient time Tt a stable magnetic field is formed and it must be taken into consideration to prevent overlapping with the time management of the current pulses, which means it is important to keep Tt<Td. It is advisable to keep Tt as short as possible by keeping the inductance low by using a parallel connection of multiple short coils (single turn), for example.

[0017] For the sake of clarity of this presentation we shall consider Tt<<Td and ignore Tt entirely. Detailed timing diagram of direct current pulses through both electromagnets EM 1 and EM 2 synchronized to master clock is shown in FIG. 2 including the forces acting on said electromagnets. Before a detailed description of pulse management I would like to point out that the same time interval Td is needed for both; for electromagnetic field to travel between the two electromagnets as well as to disappear after the current is switched off.

[0018] Detailed explanation of timing process as shown in FIG. 2 follows; [0019] Phase 1: (from time 0 to Td) Before the start both switches 108, 112 are off (no electric current through coils and no active or residual electromagnetic field). At start (t=0) current switch 112 turns on enabling current through the second electromagnet 102 while the first electromagnet 100 stays off, 108 open circuit. After time period Td magnetic field generated by current in second electromagnet 102 reaches first electromagnet 100. [0020] Phase 2: (from time Td to 2Td) At time point Td, the moment when magnetic field from the second electromagnet 102 reaches the first electromagnet 100, current through first electromagnet also switches on 108 generating Laplace propulsion force F1 on first electromagnet 100 because the magnetic field and the electric current coexist. This state (both electromagnets active) lasts until magnetic field from active first electromagnet reaches second electromagnet (time point 2Td). [0021] Phase 3: (from time 2Td to 3Td) At time point 2Td, (magnetic field from the active first electromagnet reaches second electromagnet) to prevent magnetic reaction force F2 on second electromagnet 102, electronic switch 112 on second electromagnet turns off=open circuit, meaning there is no Laplace reaction force on second electromagnet 102. After that it takes another time interval Td (from 2Td to 3Td) for the magnetic field from the second electromagnet to disappear at the location of the first electromagnet (still active) disabling Laplace force F1 on the first electromagnet in the process. [0022] Phase 4: (from time=3Td to 4Td) After time point 3Td there is no longer the magnetic field generated by the second electromagnet at the location of the first electromagnet and consequently there is no magnetic force acting on the first electromagnet, the current through the first electromagnet is no longer needed, and therefore the first switch 108 switches off at 3Td. After that the magnetic field generated by the first electromagnet needs another Td interval, until time point 4Td, to disappear at the place of the second electromagnet thus disabling all currents and magnetic fields. It is the required state for another cycle Phase 1 to Phase 4 to start and repeat as long as propulsion force F1 on the first electromagnet is wanted.

[0023] Second embodiment is the same as first, except for the second electromagnet being passive; the coil is simply short-circuited or closed with resistor. Any change in the magnetic field generated by the first electromagnet reaching short circuited coil will automatically generate current in it and consequently the Laplace forcepropulsion force. First electromagnet needs to be in switched off phase when the induced electromagnetic field from the short circuited coil returns back to the first electromagnet, preventing reaction force on the first electromagnet.

[0024] Third embodiment is the same as first, except for the soft ferromagnetic core being used instead of the second electromagnet. The soft ferromagnetic core will be polarized in the magnetic field generated by the first electromagnet and will respond with electromagnetic force acting on ferromagnetic core serving as propulsion force. It is again important to switch off the first electromagnet before magnetic field from ferromagnetic core reaches the first electromagnet thus disabling reactive magnetic force on the first electromagnet.

[0025] Furthermore, this invention is not limited to any specific embodiment and it can use various types and shapes of electromagnets or electromagnetic field sources in general, active or passive, from simple current carrying wires of any shape (with or without magnetic core) to potentially more exotic current carriers or electromagnetic field generators. Additionally, more than two electromagnetic field sources can be used to optimize and enhance propulsion force generation. Moreover, various embodiments will require different timing procedures, however always based on the same basic principle covered with this invention which is to prevent reaction electromagnetic force by switching off active electromagnetic sources at the time intervals when reaction force would naturally occur.