2 - Water Fuel Injector (Taper Resonant Cavity Chamber)
Water Fuel Injector
(Taper Resonant Cavity Chamber)
To set up, trigger, and perform Hydrogen Fracturing Process (390) of Figure (41) (see
WFC Memo 422 DA) gas ignition stage (100) of Figure (6) ... releasing thermal explosive energy
gtnt) via flame projection (16) of Figure (3B) as to Figure (14), Water Fuel Injection System (10)
of Figure (1) as to (170) of Figure (13) incorporates and uses Taper Resonant Cavity Chamber
(180) of Figure (14) to enhance operational parameters of Hydrogen Fracturing Process (100) of
Figure (6) being stimulated to activation by opposite electrical voltage fields (49/51) of Figure (3B)
as to (180) of Figure (14).
In like manner, water supply (10) of Figure (170), non-combustible gases (45) (Engine
Exhaust gases), and ambient air ionized gases (46) (air gases having missing electrons) are
uniformly intermixed when moving into, passing through and beyond fluid mixing chamber (250)
of Figure (13) by way of venturi tube-cavity (51)... allowing water fuel mixture (47/45/46) (48) to
be particle aligned by opposite electrostatically charged atoms ...positive charged gas particles (81a
xxx 81n) being directed to and attached to negative charged oxygen atom (76) of water molecule
(47); while, during the same interim period of time, negative charged gas particles (82a xxx 82n)
being directed onward ot and affix themselves ot positive charged hydrogen atoms (77a / 77b), as
illustrated in (200) of Figure (16). The resultant water fuel-mixture (48) is, now, pressurized up to
and beyond 125 lbs of fluid-pressure by Fluid Displacement Pump (170) of Figure (13), as before,
ot cause and form water fuel-droplets (48a xxx 48n) when water fuel (48) enters into, passes
through and beyond spray ports (41a xxx 41n) forming Quenching Disc Structure (190) of Figure
(15). The injected water fuel-droplets (48a xxx 48n), now, surrounds outer surface area of
exposed positive probe (33) while entering into Taper Resonant Cavity (180), as illustrated in (70)
of Figure ( B ) as to Figure (14).
Once water fuel-droplets ( xxx 48n) fully occupies open space cavity (Resonant Cavity
Zone) (35) and then exposed to applied pulsating opposite electrical voltage fields (49/51) of
voltage wave form (210) of Figure (17), the electrically stimulated water fuel droplets (48a xxx
48n) are subjected to release thermal explosive energy (gtnt) (16) undergoing Electrical-Resonant
ni a sequential manner: By first, separating water molecule (47) into its component gases (oxygen
76 / hydrogen 77a - 77b) by way of the Electrical Polarization Process (160) of Figure (25) (WFC
Memo 422 DA); secondly, by electrically attenuating the electrical-forces of the newly formed and
liberated combustible gases (76, 77a - 77b) via Energy-Priming Process (520) (see WFC Memo
424 titled "Atomic Energy Balance of Water); thirdly, by ionizing the released combustible gases by
way of Electron Ejection Process (230) of Figure (29) (WFC Memo 422 DA), as further illustrated
ni (80) of Figure (4); and finally, spark-ignite the highly destabilized combustible gases (laser
primed combustible gases having missing electrons) by electrostatic discharge (kinetic energy
agitation), as further exemplified in (280) of Figure (17); all sequential gas priming functions
occurring progressively in an instant of time.
Subsequent and repetitive formation of applied gated electrical voltage pulse-train (210a
x 210n) of Figure (17) to continued in-flow of water fuel droplets (48a xxx 48n) not only sustains and maintains Hydrogen Fracturing Process (100) of Figure (6) but, also, regulates
Thermal Explosive Energy release (16a x 16n) of Figure (14) by attenuating applied voltage
amplitude (xxx VL xxx), as graphically shown ni Figure (20F) (WFC Memo 420). This further increase in voltage amplitude xxxx VL) simply exerts a greater magnitude of opposite Electrical-
Stress (SS' - RR') of Figure (25) (TT' - UU') of Figure (29) (WFC Memo 422 DA) across
combustible gas atoms (76, 77a - 77b) which, in turns, ejects a greater number of electrons while preventing the formation of the water molecule (390) of Figure (41) (WFC Memo 422 DA) during
thermal gas-ignition (180) of Figure (17). Voltage Intensifier Circuit (220) of Figure (18) allows
Electrical-Stress variation (SS' = RR' / TT' = UU') since voltage Intensifier Circuit (220) inhibits
electron - flow (amp restriction) into voltage triggering process (210) of Figure (17) as to (100) of
Figure (6).
Electron restriction while varying voltage intensity (Va = Vn) is accomplished by
performing several functions simultaneously: Incoming pulse-train (210a xxx 210n) is adjusted ot
"tune-in" to the Dielectric Properties of Water (47) which allows Resonant Action (see WFC Memo
424, once again) to occur since the Dielectric property of water (78.54 valve) becomes a integral
part of Electronic Circuit (110) of Figure (7) as to (220) of Figure (18) ... forming a capacitor (E7 /
E8) in series with Resonant Charging Chokes (56/57) placed on opposite sides of Resonant Cavity
Zone (35) as to Figure (7) and (8) . . . forming a Resonant Pulsing Circuit (110) of Figure (7) with
setp up Pulsing Transformer (33/36), as shown in (220) of Figure (18).
Adjusting Pulse-train (210a xxx 210n) in such a way as to allow pulse off-time (T2) to be
synchronized with collapsing and re-formation of electromagnetic field coupling across pulsing
transformer (52/53) ot produce unipolar pulse frequency (Tla xxx Tin), as illustrated in (220) of
Figure (18) as to Figure (17). Pulse on-time (T1) having a predetermined constant voltage level
( xxx VL xxx) is adjusted to maximize transference of electromagnetic energy to Secondary Coil
53) during pulsing operations. The resultant and newly formed gated Resonant Pulse-train ( T1 +
2 a xxx T1 +T2n) (58) voltage amplitude (Vo xxx Vn) is, now, attenuated by Sequential Voltage
Amplitude Control Circuit (59) once step up Secondary Coil (53) produces a higher voltage level
xxxVI) above incoming pulse-train (210) since Secondary Coil (53) has a greater number of turns
of wire. Sequential Switch Circuit (59) simply switches in and out Booster Pickup Coils (61a x
61n) in series electrical hookup with Secondary Coil (53) output to elevate voltage intensity across
Resonant Charging Chokes (56/57).
Forming Resonant Charging Chokes (56/57) by using Stainless Steel Electro-Inductance
wire-material (430F / T304 or equivalent) which, when electrically pulsed transmits voltage
intensity while restricting amp flow during Resonant Pulsing operations. Together, the resistive
valve of Stainless Steel wire-coil (56/57) and its inductance generated electromagnetic field (62) of
Figure (19) opposes the movement of electrons since the dielectric valve of wire-coils (56/57)
inhibits electron exchange while the generated inductance field (62) locks onto the electromagnetic
field of the electrons ...generated coil inductance field (62) being greater in electromagnetic... [ends abruptly...]
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The "Plus Factor" is that induce external electromagnetic field (63/64) across Resonant coil-
-Tap (67) increases voltage intensity (voltage potential) still further rather than diminishes peak
voltage potential due to resistive valve of the stainless steel wire. In other words, the inductance
and capacitance valves of stainless steel induction coil (56/57) bypasses voltage drop across its
resistive load (ohmic valve of wire). This induced voltage phenomenon encourages and therefore
prevents resonant pulse frequency (58) from being impaired or altered while being electrically
transmited to Resonant Cavity (180) of Figure (14) via electrical tabs (71) and (72) of Figure (14).