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RESONANT MAGNETOMECHANICS

ABSTRACT

Unleash complimentary reaction forces in resonance there~with.

INTRODUCTION

                    To all whom it may concern be it known that I, Gaby de Wilde, artist, subject of the Dutch Queen, of Dutch nationality, a citizen of the independent monarchy of the Netherlands governed by members of the House of Orange Nassau, residence of Enkhuizen, in the Province of North-Holland the Kingdom of the Netherlands, have invented a method of extracting energy from resonant reactionforces thus allowing for the construction of perpetual motion apparatus in the most general sense thereof I hereby declare ofwhich the following specification to be a full, clear, exact and accurate description of the invention, such as will enable others skilled in the art to which it appertains to use the same as from.

RESONANT MAGNETOMECANICS

                    Throughout this document we assume magnets attached to a primary and a secondary rotors attract another. The secondary rotor initially not moving. The magnets attached to the primary rotor approach those attached to secondary rotor. The disks are positioned in the sandwich formation.

THE MUCH TO SLOW APPROACH

                    If the Primary wheel is spinning to slow the magnets will attract another then lock into place. From that point on the secondary rotor will be dragged along with the primary. Nothing useful is accomplished by this.

THE MUCH TO FAST APPROACH

                    If the Primary wheel is spinning to fast the magnets will attract another, short pulse~like jerks present some drag. Nevertheless, eventually, over~time we accomplish the same thing as with said to~slow approach. The rotors end up spinning in the same direction accomplishing nothing useful.

THE APPROACH WITHIN RESONANCE THEREWITH

                    If the primary wheel is spinning at exactly the right speed the magnets will attract another just like in the to~slow approach. Just like in the to~slow approach the magnets attract causing the secondary wheel to momentarily rotate in the opposite direction relative to the primary. Within the specific resonant speed the rotors do-not lock into place. The primary rotor still has enough kinetic energy to escape the attraction again. Slightly to fast or slightly to slow and the secondary rotor will take the same direction as the primary even-tho it is initially reversed by the interaction. Only when we find the exact resonant speed the secondary rotor will first spin then come to a full stop after the interaction.                     At the moment when the secondary rotor would normally be expected to reverse direction it does stop but just stopping doesn't prevent the primary rotor from moving away from it. As a result of this interaction the secondary rotor has now rotated in the reverse direction, we may thus expect the primary to have~also moved in it's equal and opposite direction. Evidently the interaction secondary:primary made the secondary move over distance in the exact opposite direction and when it stops the next magnet approaches and the effect perpetuates. Just like you can sometimes see the wheel cap of a car spin backwards on film.
                   Knowing that the Secondary rotor comes to a full stop with every interaction a simple speed governor applied to the primary is enough to make sure this interaction can quite easily be tuned to perfection.

CONCLUSION


                   It's not just free kinetic energy onto the secondary wheel, the equal and opposite reaction forces demand that any load applied to this secondary wheel will make our primary "decelerate" in equal and opposite direction. Where the double negative becomes a positive once again! It may not be much but application of a load does accelerate the device and the contraption is fully scalable. The load is not negatively reflected back onto the source rather the exact opposite and other way around relative thereto with it's consequences thereof.