Belsõ mágnesek vonzásán és taszításán alapulva, a Lutec 1000 folyamatosan üzemel a nap 24 órájában, 24 kilowatt energiát termelve, egy teljesen környezetkímélõ és ingyenes erõforrást felhasználva, miután egy másik erõforrásról elindítják. Nem kellenek vezetékek az energia továbbításához. A hatékonysága több mint 500%-os , míg például egy autónál ez 40%. Nem termel hõt, nincs káros kibocsátása, sem légszennyezõ anyag, beleértve ebbe az áram továbbítását is az áramfejlesztõ rendszerbõl, és csak a mágneseket kell cserélni (1300 év élethossz) és az akkumulátoregységeket (5 év élethossz).
" (...)$500,000 kell ahhoz hogy beíndítsuk a gyártást. (...) Félünk hogy elrabolják a gyerekeinket, lelõnek vagy felrobbantják a laborunkat.(...)"
(szóval azért félnek is)
Itt van az ismertetés és a honlapon lentebb a mûködése
Background of the Invention
A typical electric motor consists of a stator and rotor.
1 - The operation of an electric motor is based on the principal that an electric current through a conductor produces a magnetic field, the direction of current in an electromagnet such as a coil of wire determines the location of the magnet poles and like magnetic poles repel and opposite poles attract.
2 - The stator which is typically called the field structure establishes a constant magnetic field in the motor.
3 - Typically the magnetic field is established by permanent magnets which are called field magnets and located at equally spaced intervals around the rotor.
4 - The rotor or armature typically consists of a series of equally spaced coils which are able to be energized to produce a magnetic field and thus north or south poles.
5 - By keeping the coils energized the interacting magnetic fields of the rotor and the stator produce rotation of the rotor.
6 - To ensure that rotation occurs in a single direction a commutator is typically connected to the windings of the coils of the rotor so as to change the direction of the current applied to the coils.
7 - If the direction of the current was not reversed the rotor would rotate in one direction and then reverse its direction before a full cycle of rotation could be completed.
8 - The above description typifies a DC motor. AC motors do not have commutators because alternating current reverses its direction independently.
9 - For a typical AC motor such as an induction motor the rotor has no direct connection to the external source of electricity. Alternating current flows around field cols in the stator and produces a rotating magnetic field. This rotating magnetic field induces an electric current in the rotor resulting in another magnetic field.
10 - This induced magnetic field from the rotor interacts with the magnetic field from the stator causing the rotor to turn.
11 - An electric generator is effectively the reverse of an electric motor. Instead of supplying electricity to coils of either the stator or the rotor, the rotor or armature is rotated by physical forces produced by a prime mover.
12 - In effect a generator changes mechanical energy into electrical energy.