WFC 423DA-2 - Water Fuel Injection System

Water Fuel Injection System
Water Fuel Injection System 

 

 WFC Hydrogen Gas Management System is ideally suited as a retrofit energy system to both reciprocating (rotary piston engine) and turbine jet engines associated with the aviation industry...but in different ways: Reciprocating WFC fuel-kits can be similar to car design (340) of Figure (3 8 ) of WFC (422 DA) ; 

 Whereas, Water Fuel Injector Kit (10) of Figure (1) can alternately be used as a self-contained Fuel-unit having no pressurized vessel which converts water directly into thermal explosive energy (gtnt) on demand, as illustrated (10) of Figure (1) as to Figure (40) of Figure ( 2B 1-2 ). 

 

 

 Operationally, Water Fuel injector assembly (10) of Figure (1) as to (40) of Figure ( 2B ) performs several functions simultaneously to produce thermal explosive energy-yield (gtnt) (16) on demand: 

 First water mist (47) of Figure ( 1- 3A) is injected into fuel-mixing chamber (35) of Figure (3B) by way of water spray ports (41a xxx 41n) of Figure (3A); 

 Secondly, ionized air gases (46a xxx 46n) of Figure (3A) (laser primed ambient air gases having missing electrons) produced by Ambient Air Ionizer (80) of Figure (4) as to Figure (1) and non-combustible gases (45) of Figure (3A) are intermixed with expelling water mist (47a xxx 47n) to form Water-fuel mixture (48) by way of gas mixing disc (34) of Figure (3B) as to (30) of Figure (2A); 

 thirdly, the resultant moving Water-Fuel mixture (48) of Figure (3B) enters into Voltage Igniter Stage (180) of Figure (3B) and exposed to high intensity voltage fields (33 / 36) (typically 2,000 volts or above @ 10 Khz or above) opposite electrical polarity (E7 / E8) 

 ...which, in turn, not only performs electrical polarization process (160) of Figure (25) undergoing Dielectric Resonant (240) of Figure (30); but, also sets up and triggers Hydrogen Fracturing Process (390) of Figure (41) as to Figure (6) under control state (on demand) via electrical-static spark ignition (49 / 51) of Figure (3B)....releasing thermal explosive energy (gtnt) (16) passing beyond gas exit port (32) of Figure (3B), as further illustrated in Figure (2) as to Figure (1). 

 To ensure proper energy-flame projection and subsequent energy-flame stability, constant placement water pump (170) causes and allows ionized ambient air gases (46), non-combustible gases (45), and water (47) to be displaced under static pressure up to and beyond 125 psi respectively . 

 Energy-Flame density is enhanced and sustained by causing ionized gases (46a xxx 46n) of s pray port (42) to be deflected into liquid spray path (41), together water mist (47) and ionized air (46) are, now, directed toward and deflected through non-combustible gas spray path producing uniformed water-fuel mixture (48), as illustrated in Figure (3B). 

 Energy-Flame temperature is regulated by controlling the volume flow-rate of each fluid mediums (47 / 45/ 46) in direct relationship to applied voltage intensity (33 /36), as further stated in Figure (2B) as to Figure (3B). 

 To elevate Energy-flame-temperature still further, help increase fluid-displacement (46/47) while maintaining or reducing the volume flow rate of non-combustible gases (45) during an increase of applied voltage amplitude (Vo x Vn) of Figure (32) as to Voltage Intensifier Circuit (110) of Figure (7) and Electron Extraction Circuit (120) of Figure (8). 

 To lower Energy-flame temperature simply increase the amount of non-combustible gas (45a xxx) or reduced the fluid flow rate (45 / 46/ 47)) uniformly while lowering pulse voltage amplitude (xxx Vo). 

 To establish a predetermined or given Energy-flame temperature adjust fluid-medium (45 / 46 / 47)) and applied voltage amplitude (Vo xxx) independent of each other to obtain the desired results. 

 The resultant energy-flame pattern is further maintained by allowing the ignited,compressed, and moving gases (29) of Figure (3B) to be projected to, pass through and beyond nozzle-port (32) under pressure due to gas expansion caused by thermal gas ignition. 

 Voltage Igniter Stage (180) of Figure (3B) as to Voltage Intensifier Circuit (110) Figure (7) as to Extraction Circuit (120) of Figure (8) performs several functions simultaneously to initiate and trigger thermal explosive energy-yield (gtnt) (16) beyond normal gas burning levels: 

 Water droplets (28a xxx 28n) escaping from spray-mist (47) and exposed to high intensity voltage fields of opposite polarity 33/ 36) are stimulated to undergo Electrical Polarization Process (160) of Figure (25)...which not only separates and splits the unlike atoms of the water molecule but also causes the unlike atoms (hydrogen atoms 77a / 77b and oxygen atom 76) to experience  electron ejection (230) of Figure (29) as to (71) of Figure (8) since voltage intensifier circuit (110) of Figure (7) inhibits and prevents electron flow to enter into gas ignition process (180), as further illustrated in Figure (6). 

 The newly liberated water molecule atoms (oxygen 76 and hydrogen atoms 77a / 77b) immediately interact with laser primed ionized ambient air gases (7a xxx In of Figure 1-8) (see WFC memo 420 ) to cause the resultant highly energized and mass destabilized combustible gas atoms (93a xxx 93n) of Figure (8) to perform Hydrogen Fracturing Process (80) of Figure (7) when electrostatic force (14/16) thermally ignites ( kinetic agitation ) destabilized water-fuel mixture (93a xxx 93n) under gas compression... preventing the formation of the water molecule during thermal gas ignition....satisfying Energy Gas Detonation Equation . 

 

 which states: 

 That, whenever the mass-size of a combustible gas atom is decreased (Md), thermal explosive energy-yield (gtnt) is increased (Ein) during thermal gas combustion (Gas // Detonation.), as so illustrated in (100) Figure (6) as to (90) of Figure (5). 

 

 Incoming ambient air gases (5a xxx 5n) become laser primed and ionized when passing through Ambient Air Ionizer (Gas Processor) (80) of Figure (4) as to (10) of Figure (1) since electron extraction circuit (120) of Figure (8) not only captures and consumes ejected electrons (7a cx 7n) of Figure (6); but, also prevents electron flow into destabilizing gas process (180), as so illustrated in Figure (3B). 

 In terms of performance reliability and safety, ionized air gases (46a xxx 46n) and liquid water (47a xxx 47n) do not become energy activated (volatile) until water-fuel mixture (48) reaches Voltage Igniter Stage (180). 

 Injected non-combustible gases (45a xxx 45) retards and controls the combustion rate of the Hydrogen Fracturing Process (100) of Figure (6) during gas-ignition. 

 In other or alternate applications, laser primed ionized liquid oxygen (68) of Figure (1-10) CF* memo 420) and laser primed liquid hydrogen (69) of Figure (1-10) stored in separate fuel tanks can be used in place of fuel-mixture (48); or, liquefied ambient air gases (6) alone with source (8) can, also, be substituted as a fuel-source (48) to trigger Hydrogen Fracturing 10). 

 Additional WFC Injector Assemblies (20) of Figure (2) are arranged in cluster array (20a xxx 20n) to increase energy-yield output  (16a xxx 16n) of Figure (10 / 1 / 12). 

 WFC injector assembly (10) of Figure (1) as to (30) of Figure (2A) is design variable to be retrofitable by replacing fossil-fuel injector ports affixed to jet engines (see Figure 11), heating systems (Figure 10), rockets engines (Figure 12), or even car spark plugs (130) of Figure (9) which simply uses Water Fuel management (WFMS) system fluid-metering system (40) to control gas ignition (16), as illustrated in (40) of Figure (2B). 

 Sequential pulsing of Water Fuel Injector (20/30) of Figure (1) as to (40) of Figure (2B) is system activated by Pulse Gate Valve (190) of Figure (1) to further control a predetermined energy-flame (16). 

 In essence, then, the Water Fuel Injector system (40) simply processes and converts water into a useful hydrogen fuel on demand at the point of gas ignition...thereby, co-equally or superseding fossil-fuel safety standards... 

 especially when ionized ambient air gases (46a xxx 46n) and non-combustible gases (45a xxx 45n) are intermixed with water supply (47) prior to entering. 

 Water Fuel Injector Plug (20 / 30), as illustrated in (40) of Figure (2B) as to (10) of Figure (1).

Voltage Intensifier Coil Assembly
3-1 Coil Wrap Assembly 

 

 3-2 (VIC) Coil Assembly 

 

 3-4 Inner Core Bobbin 

 

 3-5 Outer Core Bobbin 

 

   

 3-6 Pulsing Core 

 

 3-7 VIC Amp Inhibitor Coil Ass'y 

 

 3-8 Multi-Coil Spool 

 

 3-9 VIC Mount Base 

 

 

 

 

 

 

 3-10 Mount Base (End View) 

 

 

 

 

 

 

 3-11 VIC Cover Plate 

 

 

 

 

 

 

 

 

 

 3-12 Diode Holder 

 

 

 

 

 

 

 3-13 Flat Seal 

 

 3-14 WFC Voltage Ignition Wire 

 

 3-15 VIC Mount Plate 

 

 3-16 Mount Bar 

 

  

Electronic Circuit Design
Pulse Width Modulated Differential Solenoid Circuit 

 

 

 

 Steam Resonator Driver Circuit 

 

 

 

 Data Link Flow Chart 

 

 

 Air Pressure Logic Circuit 

 

 

 Water Heat Logic Circuit 

 

 Pulse Shift Control 

 

 

 Gas Rate Feedback Control 

 

 Primary Voltage Amplitude / Pulse Gate Control 

 

 Emergency Reset Circuit 

 

 Water Probe Circuit 

 

 Thermocouple Circuit 

 

 Rotational Pulse Generator 

 

 Delay Pulse Drive Circuit 

 

 Water Level Control 

 

 Voltage Intensifier Coil (VIC) Assembly 

 

 Emergency Shutdown Circuit 

 

 Regulator Isolation 

 

 Digital Pulse-Width Dual-Solenoid Control 

 

 

 Laser Accelerator Matrix Circuit

WDMS Laser Acceleration Cards
RE: WATER FUEL INJECTION SYSTEM Memo WFC 423 DA Gasoline Vs "Water as Fuel" : 

 

 50 hp Internal Combustion Engine 1ml/min gasoline consumption rate (on-road tested) @65 mph ÷25. hydrogen-fuel of water = 44.4 ml/min water flow rate ÷60 sec. = 740 ml/sec. water-fuel consumption rate@ 65m.p.h. 

 Water Injection Cycle 030, г р ÷ 60 sec. = 50 engine revolutions/sec ÷ 2 (Distributor Turn Ratio) 52 Rotor revolutions/sec x 4 Water-Fuel Injectors = 100 Injection cycles/sec. 

 Thus, 0.47 ml/sec water-fuel rate ÷ 100 injection cycles/sec. = 7.4 ul Water Droplet / injection cycle Voatlge Intensifier Circuit 

 40,000 volts @1ma =40 wats of applied electrical power 40 watts ÷ 12 volts battery = 3. amp/hr (current) draw capacity 00amp/hr battery ÷3. amp/hr current consumption =30.3 battery-life without recharging 

 Distributor Firing Sequence 25 Rotor Revolution / sec ÷ 1000 = 25ms / Rev. Water Inject-Time & applied Pulse-Voltage 

   

 WFMS Laser Acceleration Card A1 

 

 WFMS Inject Card A2 

 

 WFMS Inject Card A3

Differential Air-Gas Inlet Control
Differential Air-Gas Inlet Control Diagram 

 

   

 Gas Processor Assembly 2 

 

 Gas Processor Assembly 

 

 Mount Base 

 

 Mount Base 

 

 Mount Base 

 

 Upper Cap Assembly 

 

 Interlocking Cap 

 

 Retaining Cap 

 

 Optical Lens 

 

   

   

 WFMS Gas Processor Card A4

Water Fuel Injector (Taper Resonant Cavity Chamber)
Taper Resonant Cavity Chamber 

 To set up, trigger, and perform Hydrogen Fracturing Process (390) of Figure ( 3-42 ) (see WFC Memo 422 DA ) gas ignition stage (100) of Figure (6) ... 

 (390) of Figure ( 3-42 ) 

 

 (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). 

 

 flame projection (16) of Figure (3B) 

 

 

 

 Water Fuel Injection System (10) of Figure (1) 

 

 

  (170) of Figure (13) 

 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 to and affix themselves to 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, to 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). 

 

 Fluid Displacement Pump (170) of Figure (13) 

 

 

 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 (3B) as to Figure (14). 

 

 (70) of Figure (3B) 

 

 

 

  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 (2 8 0) of Figure (17), the electrically stimulated water fuel droplets (48a xxx 48n) are subjected to release thermal explosive energy (gtnt) (16) undergoing Electrical-Resonant in 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 in (80) of Figure (4); 

 

 Electron Ejection Process (230) of Figure ( 29 ) 

 

 

 (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 xxx 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 in Figure (20F) ( WFC Memo 420 ). 

 

 Hydrogen Fracturing Process (100) of Figure (6) 

 

 

 

 Thermal Explosive Energy release (16a xxx 16n) of Figure (14) 

 

 

 This further increase in voltage amplitude (xxxx V L ) 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) 

 

 Figure ( 25 ) 

 

 

 

 

 Figure ( 29 ) 

 

 

 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 (1 4 ). 

 

 (390) of Figure ( 41 ) 

 

 

 (180) of Figure (1 4 ) 

 

 

 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). 

 

 

 voltage triggering process (210) of Figure (17) 

 

 

 (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 to "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 value ) becomes a integral part of Electronic Circuit (110) of Figure (7) as to (220) of Figure (18) 

 

 Electronic Circuit (110) of Figure (7) 

 

 

 

 (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 step-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) to produce unipolar pulse frequency (T1a xxx T1n), as illustrated in (220) of Figure (18) as to Figure (17). 

 

 (220) of Figure (18) 

 

 

 

 Figure (17) 

 

 

 Pulse on-time (T1) having a predetermined constant voltage level (xxx V L 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 + T2a 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 (xxxV L ) 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 xxx 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... ] 

 

 

 The Following Page 1-7 was not available 

 

 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 values 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 transmitted to Resonant Cavity (180) of Figure (14) via electrical tabs (71) and (72) of Figure (14).

Funneling Effect
Enhancement of the operational parameters of Hydrogen Fracturing Process (100) of Figure (6) is further exemplified when incoming Resonant voltage-wave (58) of Figure (18) electrically transmitted across Resonant Cavity Zone (35) during water injection cycle... 

 causing Resonant Cavity Zone (35) to function and perform as a voltage wave-guide (86) of Figure (14) since the gradual decrease in cross-sectional circumference area (85) of Figure (14) is in linear progression ... reducing both voltage surfaces areas (83/84) in parallel space relationship from larger segmental area (85a) to smaller segmental area (85n). 

 

 This resultant " Funneling Effect " (260), now, allows voltage amplitude (Vn) wave-form (58) to travel the length of Resonant Cavity Zone (35) from Start-Point (85a) to End-Point (85n) increasing voltage intensity (xxx VL = Vn) as parallel voltage surfaces (83/84) diminishes in size relationship (85a ~ 85n), as illustrated in (210) of Figure (17). 

 This "progressive" increase in voltage intensity (V L ~= Vn) due to the " Funneling Effect ", now, allows several gas processing functions to occur in a instant of time: 

 

 

 Voltage amplitude level V L of Pulse-wave (58) is predetermined ( 20,000 V.D.C. typically) to start and cause Electrical Polarization Process (160) at a relative rapid rate of gas production at segmental point (85a) when voltage point (V L xx Va) is reached. 

 As voltage intensity increases (V L x Va x Vb) onward segmental point (85b), Energy Pumping Action (520) of Figure (4-3) ( WFC Memo 424 ) as to (280) of Figure (3 4 )  ( WFC Memo 422 DA ) is activated to peak performance levels. 

 

 (520) of Figure (4-3)  

 

 

 

 (280) of Figure (3 4 ) 

 

 

 At segmental point (85c) voltage intensity (VL x Va x Vb x Vc) is increased sufficiently enough to propagate Gas Ionization Process (230) of Figure ( 3-30 ) ( WFC Memo 422 DA ). 

 

 

 At termination point (85), voltage intensity (VL x Va x Vb x Vc x Vn) is, now, increased to the point to cause Gas Ignition as Combustible Gas Atoms (76, 77a - 77b) which are, then, expelled from Gas Nozzle Port (87) of Figure (14) under dynamic pressure to allow thermal gas expansion (16) ... releasing thermal explosive energy (gtnt) beyond and away from Resonant Cavity Chamber (180), as illustrated in Figure (14). 

 

 

 To prevent pre-ignition of gases traveling toward Exit-Port (87), Resonant Cavity (35) open space (open resonant cavity) parallel dimension between positive voltage surface (82) and negative voltage surface (83) is small enough (typically .010 or so) to function as a Quenching Circuit , as illustrated in Figure (24SD) (missing image) ( WFC Memo 420 ). 

 

 To increase energy levels (16a xxx 16 L = 16n) of Hydrogen Fracturing Process (100) as to (390), even further, simply switch-on additional Booster Coils (61a x 61 L - 61n) in sequential order to increase voltage intensity (VL ~ Vn ~ Vm) to higher magnitude of " Electrical Force " (Vma xxx Vmn) which is due to the inductance/capacitance values of each succeeding coil-structure (61a x 61n) forming Booster coil-Assembly (250), as illustrated in (240) of Figure (20). 

 

 

 

 

 To return or lower Voltage Intensity (xxx Vmn) to Secondary Voltage Level (71), once again, inductance core-slug (73) (magnetic core material) advances ( via solenoid Control 74 ) toward, passes through inside coil-wrap (250) in linear manner to "Switch-Off" each adjacent coil-stage (61a xxx 61n) by " Shunting " or " Redirecting " induced voltage intensity (Vmn xxx Vma) to its respective electrical out-put leads (72n - 72c - 72b - 72a), as shown in Figure (20). 

 This " Shunting Effect " occurs when the magnetic field strength of each individual coil-structure (61) ( being electrically energized ) induces and forms magnetic core-field (75) which opposes and stops current flow within the exposed coil-stage  (61a-61b-61c-61n). 

 This resultant " Shunting Effect ", now, allows voltage intensity (Vma = Vmn) to be placed across Resonant Cavity Zone (35) to not only compensate for water impurity that might alter the operational parameters of Hydrogen Fracturing Process (100) as to (390) but, also, provide "Instant" "Power-Boost" when needed. 

 

 

 The established "Power Boost" energy level (16a xxx 16n) is changeable, however, by, simply, electrically moving or displacing (back and forth movement) Core-Slug (73) to another stop-location (72)... adjusting energy-level (16a xxx) on demand. 

 In alternate form, Core-Slug (73) is replaced by a series of Choke Coils (77a xxx 77n) arranged in such a way as to increase voltage Intensity (Voltage Pulse Amplitude) (V L ~ Vn xxx) digitally by sequentially switching-on / switching -off Choke Coils (77a xxx 77n) to allow applied Voltage Intensity (V L ~ Vn xxx) to be placed across Voltage Expander Coils (78a xxx 78n) in  direct relationship to electrically energized shunt-coil (76). 

 For example, as adjacent Shunt-Coil (76b) is switch-on while, simultaneously, Choke Coil (76a) is switch-off by Electronic Switch Circuit (79), Voltage Intensity (V L ~ Vn xxx) is increased due to inductance / capacitance of Voltage Expander Coil (78a) which is, now, added to Electrical Circuit (250) by electrical pathway (82a) since electromagnetic coupling field (76b) prevents electron flow to cause open circuit (82b)... 

 (missing content) 

 thereby establishing Voltage Level Logic Function (260) which is electronically transferable in sequential order (260a xxx 260n) by Laser Acceleration Control Circuit (4-4) of (220) of Figure (18). 

 

 thereby, attenuating voltage amplitude (voltage intensity) beyond Secondary Coil (53) voltage levels (71), as illustrated in (220) of Figure (18). 

 

 Attenuating variable voltage amplitude (72a xxx 72n) in conjunction with incoming gated pulse-train (210a xxx 210n), now, expands gated pulse width (76a xxx 76n) as voltage amplitudes (Vo xxx Vn) increases, forming step up voltage wave Form (77) of Figure (17). 

 

 This newly formed synchronized and repetitive dual expanding voltage wave form (77a xxx 77n) is further enhanced by " Funneling Effect " (260)... maximizing voltage dynamic across Resonant Cavity (35) always subjecting and exerting increase " Electrical-Stress " (SS'-RR' / TT'-UU') of opposite polarity across Hydrogen Fracturing Process (100 / 390) to the point of gas ignition.

Amp Inhibiting Circuit Vs Voltage Enhancement
Amp Inhibiting Circuit Vs Voltage Enhancement 

 Beyond amp restricting characteristic of said Amp Inhibiting Circuit of Figure (1-18) as to VIC Dual Single-coil Assembly (Figure 1-19A) and VIC Bifilar-Wrap Coil Assembly (Figure 1-19B), the spiral-wrapped coils being paired together, also, causes voltage level enhancement beyond applied voltage input since the " Distributed Capacitance " (Cl xxx Cln =C2a xxx C2n) / "Distributed Inductance" (FL1a xxx FL1n = FL2a xxx FL2n) of said "Bifilar" wrapped coils encourages the compounding effect ( increasing magnetic field-strength during each pulsing cycle ) of electromagnetic field-strength (Rpla xxx Rpin = Rp2a xxx Rp2n) ( mutual induction ) when applied Pulse-Voltage Frequency (49a xxx 49n) passes through the positive energized Resonant Charging Choke (56). 

   

   

 

 Figure 1-19A 

 

 

 

 Figure 1-19B 

 

   

 Furthermore, the paired coils-wires opposite voltage potential [ positive electrical attraction force (B+) equaling negative electrical force (B-) ] [herein called " Electrical Stress " (SS' = RR") as to (160) of Figure (3-26)] are always equal in electrical magnitude/electrical intensity since the wire-length of each coil are the same. 

 Pulse-Voltage repetition rate sets up the step-up electrical charging effect (Figure 1-3) since the "Resonant Cavity" functions as a Capacitor ER ) due to the dielectric value ( Resistance to amp flow ) of water which becomes an integral part for the VIC Circuit, as so illustrated in (650) of Figure (7-4). 

 

 Figure 1-3 

 

 

 

 (650) of Figure (7-4) 

 

 

 The resultant voltage enhancement ( Voltage Amplitude ) can exceed 40 kilovolts to instantly convert water (droplets) into thermal explosive energy (gtnt), as so illustrated in voltage Intensifier Circuit Diagram (Figure 1-18). 

   

 

 

 Both VIC Dual Single-Coil (Figure 1-19A) and VIC Bifilar-Wrap Coil (Figure 1-19B) function similarly without incurring amp influxing. ( See WFC U.S. Patent Validation Report titled "Natural Water Hydrogen Generation System filed September 16, 1981 ) 

 

 

 Figure 1-19A 

 

 

 

 Figure 1-19B

Water Fuel Injector Illustrations
  

 2-1 Taper WFC Injector Assembly 

 

   

 2-2 Plug Housing 

 

 2-3 Water Inlet Housing 

 

 2-4 Positive Probe Assembly 

 

 2-5 Clamp Nut Assembly 

 

   

 2-6 Ceramic Insert 

 

  

Steam Resonator Assembly
Steam Resonator Ass'y 

 

 S/R Mount Base 

 

   

 Excitor Tube Ass'y 

 

 End Cap 

 

 Terminal Cap 

 

 Insulation Block 

 

 Terminal Post Ass'y 

 

  

Cover Page