Capacitance (Cd)
Capacitor (E9/E10) of Figure (7-1) as to Figure (650) of Figure (7-4) in direct relationship to Water Gap (616) becomes Taper Resonant Cavity (720) of Figure (7-11) as shown in (590) of Figure (6-2) since Water Gap (616) is occupied by a dielectric liquid (Re) as herein before identified as natural water (85) having no electrolyte added thereto
|
Figure (7-1)
|
Figure (650) of Figure (7-4)
|
|
(720) of Figure (7-11)
|
(590) of Figure (6-2)
|
... generally rain water (85f) (750) of Figure (7-14) being almost free of contaminates due to Water Evaporation Process (532) of Figure (5-6) ... rain water (850 being an liquid-insulator that restricts the flow of amps
|
(750) of Figure (7-14)
|
(532) of Figure (5-6)
|
... a resistive liquid (having an ohmic value of 78.54 ohms) that takes on an "Electrical Charge" when applied voltage Potential (66/67) of Figure (7-1) as to (650) of Figure (7-4) causes and sets up Molecular Polarization Alignment (617) of Figure (7-4) by way of electrical molecular rotation (opposite electrical attraction force to rotate and position particle alignment) of each water Molecule (85a - 85b - 85c - 85n). being subjected to opposite electrical attraction forces (SS' - RR').
|
(66/67) of Figure (7-1)
|
(650) of Figure (7-4)
|
In like manner, the stainless steel (s/s) T304 material that forms Voltage Zones (E9/EI0) undergo particle alignment of its atomic structure within the atomic infrastructure of plate-material (E9/E10) when exposed to the same applied electrical voltage fields (66/67) after a pre-set time
... causing molecular electrical movement to occur within the surface-material (E9/EI0)
... which, after occurring, the newly formed molecular electrical orientation (625a xxx 625n) of Figure (7-4) remains in electrical atomic alignment after pulse off-time (T2) aiding the transference of voltage potential during pulse on-time (T1)
|
Figure (7-4)
|
.. allowing the resultant Surface Polarity Effect (skin effect) (624) of Figure (7-7) to supply a sufficient residual atomic "Electrical Charge Field" to help maintain molecular alignment of water atoms (617) during pulsing operations, as illustrated in (680) of Figure (7-7).
Inherently, then, Resonant Cavity (720) of Figure (7-11) as to (650) of Figure (7-4) forms capacitor (ER) of Figure (7-1) when the dielectric liquid of water (85) is placed or injected between electrical conducting plates (E9/E10) while applied voltage Potential of opposite polarity (66/67) is directly exposed to Water Molecules (85a xxx 85n), as depicted in Taper Resonant Cavity (590) of Figure (6-2) as to (650) of Figure (7-4).
|
(720) of Figure (7-11)
|
(650) of Figure (7-4)
|
|
Figure (7-1)
|
(590) of Figure (6-2)
|
Inductor (614) and Inductor (615) of Figure (7-1) as to (670) of Figure (7-6) is wound or coil-wrapped (see multi-layer equation Eq. 20) in such a manner as to increase the magnetic flux intensity (D1a xxx D1n) of Figure (7-3) as to (580) as to Figure (6-1) in reference to (710) of Figure (7-10) between the turns (618a xxx 618n) of coil-wrap (640).
|
(670) of Figure (7-6)
|
(710) of Figure (7-10)
|
|
Figure (7-3) as to (580)
|
(580) as to Figure (6-1)
|
The circular-spiral turns of wire (forming parallel electrical surfaces) is separated by an Insulated Dielectric Coating Material which forms a series of capacitors (Cda xxx Cdn) when magnetic flux-lines (619a xxx 619n) produce Electromagnetic Coupling Field (621) during pulse on-time (T1), as illustrated in (640) of Figure (7-3) as to (690) of Figure (7-8).
|
(640) of Figure (7-3)
|
(690) of Figure (7-8)
|
The series resistance value (Rs) in (670) of Figure (7-6) as to (690) of Figure (7-8) and (670) of Figure (7-6) is determined by the composition of the wire material in terms of its ohmic value (electrical resistivity) per given length and diameter cross-section:
|
(670) of Figure (7-6)
|
(690) of Figure (7-8)
|
Resonant Charging Chokes (614/615) 430F/FR 36 AWG (.006) stainless steel (s/s) wire equals 60 micro ohms per centimeter;
Primary Coil (622) 22 AWG (.028) copper wire equals 5.1933 ohms per pound weight;
Secondary Pickup Coil (623) 35 AWG (.007) copper wire equals 13K ohms per pound weight.
"Pyre-ML" trade name "Himol" polymer coating-material is used to impart thermal and mechanical resistance to the stainless steel (s/s) wire (614/615) coating; both magnet wire sizes (622/623) uses solderable Nysol (Polyurethane Nylon Jacket) insulation enamel coating as a electrical shield-material
... all dielectric coatings having an effective 3KV per mil dielectric value and formulated specifically to endure automotive temperature range from -40 C to 155 C.