PULSE ATTENUATION CIRCUIT

Objective: Voltage Disassociation of the Water Molecule.

A) VARIABLE POWER SUPPLY:

• Purpose: (See (1) of Figure 9)
  • Any type of conventional A.C., to D.C. or D.C. power supply (non-regulated) where an adjustable voltage range from less than one volt to 110 volts and up (first-stage to voltage attenuation).

B) VARIABLE PULSE VOLTAGE FREQUENCY GENERATOR:

Purpose: Not to allow a constant voltage source to be applied to excitor array (voltage zones) while attenuating voltage amplitude for gas-rate control.

Circuit Stage: (1) (2) as to (3) of Figure 9

Optocoupler (3) is a photosolation switch that when triggered by pulse frequency generator circuit (2) causes power supply voltage (1) to be attenuated as per Figure 9A, setting up a pulse voltage frequency. By varying the triggering rate of said pulse generator (2) from 1HZ to 1MHZ, said pulse voltage frequency (9A) is likewise varied.

Phototransistor of said optocoupler (3) now allows said pulse voltage frequency amplitude (Va-Vn of Figure 9A) to be varied from less than one volt to over 110 volts via said variable power supply (1).

Circuit Function:

1. The variable pulse voltage frequency (9A) is adjusted to keep amp flow restricted during first-stage to amp restriction by allowing said voltage amplitude (Va-Vn of Figure 9A).
2. The variable pulse voltage frequency amplitude (Va-Vn of Figure 9A) is directly related to hydrogen gas production on demand (second stage to voltage attenuation).
3. Both above said functions can be performed simultaneously or apart.

C) VARIABLE GATE CIRCUIT:

Purpose: To switch off and on said generated pulse voltage frequency (9A) at a variable time rate while maintaining said voltage amplitude control (Va-Vn of Figure 9A).

Circuit Stage: (4) (5) as to (6) of Figure 9.

     Optocoupler (4) is another photoisolation switch that when triggered by variable gate circuit (5) (a second variable triggering circuit) causes said pulse voltage frequency wave form (9A) to be altered as shown in Figure 9B. The gated pulse train (16, on time) as to (17, off-time) is adjustable from 1% to 100% duty time. As on-time (16) increases, off-time (17) proportionally decreases, allowing more voltage pulses to be applied to said excitor's array (Va-Vn of Figure 9A) (ER). 

To reduce the number of voltage pulses, simply reverse the pulse-train frequency.

Once the gated pulse train (15) is set as to maximizing gas production, the duty-cycle pulse (15) is now varied from one duty-pulse per second alternation (15a) to one hundred duty-pulses per second duration (15n).

The voltage amplitude (Va-Vn of Figure 9A) remains variable as to gas needs.

Of course, optocoupler (4) gates on power transistor Q1 as herein described.

Circuit Function:

1. The adjustable pulse-train simply "concentrates" or time-regulates the applied pulse voltage frequency (9A), allowing for higher voltage amplitude (third-stage to voltage attenuation).
2. The variable gated-pulse (15) is now adjusted to reduce amp flow further while allowing voltage amplitude (Va-Vn) and pulse voltage frequency (9A) to be adjusted to "tune-in" for higher gas-yields (second stage to voltage attenuation).

D) VOLTAGE INTENSIFIER CIRCUIT:

Purpose: To step up power supply voltage (1) while maintaining said variable voltage amplitude (Va-Vn) control, said variable pulse frequency (9A) control, said variable gate (9B) control, and performing a third, fourth, and fifth step to amp restriction.

Circuit Stage: (6) (7) as to (8)

1. As power transistor Q1 is actuated to produce variable waveform (9B), the output wave form (9B) is now superimposed onto a primary coil wrap around a secondary coil of greater size (more turns of wire), forming a voltage intensifier transformer, see Figure 9. The primary coil is composed of copper wire, whereas the secondary coil is composed of resistive wire. Both types of wire are coated with an insulated material to prevent electrical shorting.
2. Opposite to the input-to-output leads, the two said coiled wires are joined together to form an electrical ground. Only transformer paper is used to wrap said coils.
3. By way of transformer-action (electromagnetic coupling), said waveform (9B) is now transferred to said secondary coil, performing voltage amplification while said pulse-train remains the same. The step-up voltage amplitude is, however, directly related to power supply voltage (1) and attenuated during gas production. The pulse-train is likewise attenuated as herein described.

To help prevent amp leakage from occurring during gas production, said resistive wire is used to retard amp flow through said secondary coil (8) as amp restriction and fourth-stage to voltage attenuation.