Torsion Field Generator

Figure 1.

Circuit Description & Theory

A variable AC voltage is applied to D1 from the AC variac and the output full wave DC is filtered by capacitor C1 and applied through the primary of  T1 to Power Transistor Q1's collector. Oscillations to the Q1 base are started by the network consisting of R2, C3,  the Stator 1 coils, C4 - C5 and  feedback winding (FB Coil 1) around Stator 1's core. The system is brought into resonance by adjusting the Variac output and R3 so that the AC voltages across C4 and C5 are stabilized at around 85 percent of the C4, C5 capacitor's maximum voltage ratings.     

After resonance is achieved with M1's Stator coils and capacitors C4/C5, and waveforms are observed to be stabilized with an oscilloscope, a Pulse Generator System is switched on and  sends low frequency signal pulses to the double pole Relay K1. When the contacts close, Circulating reactive energy from the C4/C5/M1 network is dumped into the windings of Stator 2 (M2). When the K1 relay contacts open, the C4/C5/M1 network is again allowed to ring up to full resonance. This cycle of ring ups and discharges is continued for the full duration of the test.

Description, Comparative Dimensions and Arrangement of Stator Components, and operational characteristics

The M1 stator core is a 5 inch diameter by 3 inch high ferrite composite toroid with 4 saddle coils arranged symmetrically inside the core. The M2 stator core is made of 5 stacked rolled steel flat washers, 1-1/8" ID , 2" OD @ 1/8". with 20 windings, each of # 28 magnet wire in each quarter section for a total of 80 turns.

The smaller M2 Stator core is placed just underneath  the M1 core so that the cores are concentric along a common Z-axis so that the motor forces generated not only provide rotation the particle within the field, but propulsion of the particle  normal to the Z -axis as well     The M1 core is of a high audio frequency design (15-20 Khz) of ferrite composite, similar to an ordinary color Television or computer monitor Deflection Yoke.

Various kinds of relay types could be chosen for K1 for different experimental modes. In the type of relay depicted in the schematic, both sets of contacts close simultaneously. However it may be advantageous and more consistent with the cyclone analogy if while one K1 relay contact opened, the other one closed (and vice versa), thereby enabling a low frequency (the frequency of the pulses fed to the relay by PG1) rotating magnetic field to appear in the M2 core as well.

Needless to say, various kinds of iron samples, constituting temporary rotors, are placed in the bore of M2 to observe any unusual effects that may occur.

Proposed Modification to above suggested 7/01/04 :

Sketch 1