HELTA and Energy Conversion Theory Toolkit (ECTT)

[evolvingape]

Here is Part 6 of Energy Conversion Theory:

The Resistor.

A Dry Cell has two functions within a hydroelectrolytic system. It is a series of plates with flow holes, that cause a resistance to the passage of fluid within the Mechanical System. A blockage. It also performs the same function in the Energetic System with the plate gap a controlled variable.

Resistance to Fluid Velocity is converted to Fluid Pressure.

Resistance to Electrical Potential Balancing via Arcing is converted to Fluid Molecular Dissociation of a Stable Fuel to a Combustible Gas.

Mechanical System Pressure increases efficiency of Electrical Dissociation to HHO.

Cost in this System is the Energy for Self Sustaining is provided by Closed System 2 HHO Power Output.

Seems a waste to me to use HELP Output Pressure as Velocity to convert back to Pressure again and pay for that from CS2 HHO.

This is why I developed the HELT. To use the HELP Pressure Potential to drive a Turbine and pay the cost of Self Sustaining HHO production within CS1.

I am sure OU Minds can find a place for the Resistor in the Electro Lytic Fluid System.

Rob Mason

[evolvingape]

Here is Part 7 of Energy Conversion Theory:

Timing is Critical in any Movement.

The HELP and Dry Cell Resistor are a viable proposition for an ELFS Circuit.

The Resistor is Solid State and as such has no moving components. If we wanted to achieve PWM of the Resistor via Mechanical means then the device shown in figure 7.1 below would achieve this.

A Pulley ratio power take off from the HELP would give us control over the Frequency of the PWM. The HELP is providing the Pressure for CSC and also the timing rotation for PWM of the Resistor.

The Input Slip Rings are powered direct from the DC Battery Bank which is acting as the Regulator in the circuit.

The Output Slip Rings are constructed in such a way that 180 degrees of the OD is a conductor and 180 degrees of the OD is an insulator.

These rings if mounted 180 degrees out of phase to each other will create PWM Pulsing of the Resistor 180 degrees out of phase.

By using a Slip Ring design that is 180 degrees PB2 Phosphor Bronze, laser cut from plate, and the other 180 degrees cast from high temperature plastic. The ring when mounted in a Lathe can be turned smooth on its OD creating a good surface for the Brush to run on.

Trial and Error will be required as depending on the Amps required the plastic may suffer pitting and melting from Arcing at the transition point. Ceramic Insulator may be a better option than Plastic, but more difficult to construct.

The Pulsed HELP will not require a separate PWM Slip Ring Assembly as the Two Input Slip Rings are mounted on the HELP Secondary Shaft and receive timing control from the DC Motor Output Shaft.

1 Rotation = 360 Degrees = 100% Duty Cycle

1/2 Rotation = 180 Degrees = 50% Duty Cycle

Frequency controlled by Rotary Moment RPM

(Note: I have added the Duty Cycles for the PWM Slip Ring Assembly to both image 7 and 7.1)

RM