Capacitance Reactance

Capacitance Reactance is determined by the insulation resistance (Rs+Re) and Inductance (L1/L2) interacting together during D.C. Pulsing. 

 Dielectric property of water opposes amp leakage (Re) while another property of water takes-on an " Electrical Charge ". 

 Water temperature (Rt) (cool-to-the-touch) keeps (Re) constant since amp flow remains minimal. 

 Plate Inductance (Lc) is Inductance Reactance of Inductor (L1 ) and Inductance Reactance of Inductor (L2) in series with Resonant Capacitor (140 -170) of Figure (7-6) as to (690) of Figure (7-8). 

 

 Resonant Capacitor (140 -170) of Figure (7-6)  

 

 

 

 (690) of Figure (7-8) 

   

 

 In terms of Component Reactance , Inductors (L1/L2) should always be larger than Capacitor (ER) of Figure (7-2) in order to maximize amp restriction to enhance " Voltage Deflection " (SS' - 617a xxx 617n - RR') of Figure (7-4) and, is expressed by : 

 

 Capacitor (ER) of Figure (7-2) 

 

 

 

 " Voltage Deflection " of Figure (7-4) 

 

 

 

 

 Whereas , 

 Capacitor (ER) should remain relatively small due to the dielectric value of water to obtain maximum Thermal Explosive Energy-Yield (16a xxx 16n) of Figure (4-5) and subsequently establishing Quenching Circuit (370) of Figure (3-40) to prevent gas ignition inside traveling voltage wave-guide (590) of Figure (6-2) as to (730) of Figure (7-12) 

 

 Quenching Circuit (370) of Figure (3-40)  

 

 

 

  (590) of Figure (6-2) 

   

 

 

 (730) of Figure (7-12)  

   

 

 ... to bring-on and trigger Hydrogen Fracturing Process (390) of Figure (3-42) once liberated and expanding water gases (100) of Figure (4-8) passes beyond exit port (E9d) 

 

  (390) of Figure (3-42)  

 

 

 

 

 (100) of Figure (4-8) 

 

 

 ... activating Voltage Ignition Process (90) of Figure (5-5) 

 

 (90) of Figure (5-5) 

 

 

 ... utilizing Dynamic Voltage Potential (600) of Figure (6-3) of opposite electrical stress (SS' - 617 - RR') to cause thermal atomic agitation (90) of Figure (4-7) (kinetic heat by atomic motion) 

 

  (600) of Figure (6-3)  

 

 

 

 

  (90) of Figure (4-7) 

 

 

 which, when occurring at gas exit port (32) of Figure (4-5), spark-ignites expanding water gas-fuel (45/46/47) of Figure (4-5) during water inject cycle (70) of Figure (4-5) 

 

 Figure (4-5) 

 

 

 ... releasing thermal explosive energy (gtnt) (16) under control state.