ADVANCED WATER HEATER UTILIZING ARC-FLASHPOINT TECHNOLOGY

Abstract

The newly discovered, Arc-Flashpoint Technology (AFPT) is the subject of several contemporaneously filed inventions teaching the combining of the properties of ionic plasma with nucleomagnetics as is further disclosed in the Amo Vigen Scrunched Cube Atomic Model (AVSCAM invention). By utilizing dissimilar metals in a special crucible, while a high voltage, low amperage, pulse modulated electrical current is passing between a Cathode part to an Anode part in an aqueous liquid, free floating ions are released in such abundance, that the amount of energy delivered into the system is fully transferred into heat just from the water molecules, by the explosion of the plasma released Hydrogen and Oxygen gasses when the two gasses recombine in the said crucible and ignite to form a controlled explosive reaction that in the process generates a massive amount of heat. The nucleomagnetics feature (AVSC Method) comprised within the system, draws the free ions from the unwanted saline (if brine water is used) which not only generates an unusual amount of heat instantaneously, but also creates potable drinking water at the same time, due to the sequestration of the sodium component.

Claims

1. A means and method of creating aqueous ionic plasma from H2O comprising two dissimilar metals such as Tungsten on the one hand and Nickel on the other hand, by passing a low amperage electrical current through the said aqueous solution from the anode part to the cathode part to create heat energy.

2. The method described in claim 1 further comprising a solid nickel ring as the cathode part and a thin Tungsten wire comprising the anode part, and both the anode and cathode being housed in a configuration similar to a spark plug further comprising a ceramic insulator part, and a threaded attachment part herein described as the Arc-Plug.

3. The method described in claim 1 and claim 2 further comprising a pulse modulated RF signal driving the current between the said anode and cathode part(s).

4. The method described in claims 1 thru 3 further comprising an electromagnetic part that is used to separate the ionic plasma stream into its several parts, one the one hand the hydrogen component, on the other hand the oxygen component and the resulting sequestered remains being the undesired waste or contaminated part which is then vacuumed into a waste disposal reservoir.

5. The method described in claim 4 further comprising an array of magnets or pulsed electromagnetic array as described in claim 4 however the multiple array being deployed as to separate the contents of the aqueous solution by molecules or atomic weight into the several elements as might be found in the said aqueous solution such that desired atomic compounds or base elements such as lithium, boron, sodium chloride, may be individually separated out of the solution and then either saved for further usage, or discharged as waste water.

6. The methods described in claims 1 thru 5 further comprising encapsulating the entire plasma generator and said components described in claims 1 thio 5 in a metallic crucible of some conductive material such as stainless steel for example.

7. The methods described in claims 1 thru 6 further comprising the said crucible in claim 6 being encased in a non-heat conductive material such as ceramics or porcelain for example.

8. The method described in claim 3 further comprising a three phased reversed pulse RF modulated signal which changes polarity on a variable time base docked system.

9. The method described in claim 2 wherein the said cathode part is a floating ground loop and the metallic said metallic crucible described in claim 6 is connected to one side of the said pulsed RF modulated three phased reversible current power supply and the anode part is connected to the opposite side of the said pulsed RF modulated three phased reversible power supply.

10. The methods described in claims 1 thru 9 further comprising a series of interconnected metal crucibles comprising the various components of claims 1 thru 9 and the said plasma ion stream is steered from crucible to said connected crucible in the array by a vacuum pressure pump connected to the last crucible in the array.

Description

A BRIEF DESCRIPTION OF THE DRAWINGS

[0056] FIG. 1 depicts a drawing of the Arc-Plug as might be found in the preferred embodiment of the present invention for example. It might be noted that the arc-plug has threads so it can be removed and replaced easily, if and when, it wears out.

[0057] FIG. 2 depicts the crucible portion of the system showing the Arc-Plug, the Input and Output of the chamber, and the sealed, rotating neodymium magnetic ion steering system, as might be found in the preferred embodiment of the present invention for example.

[0058] FIG. 3 depicts the End to End system components of the present invention as might be found in the preferred embodiment of the present invention for example.

[0059] FIG. 4 depicts the Magnetic Configuration Detail of the preferred embodiment of the present invention for example. This may be configured in one, two, or all of the three axis.

[0060] FIG. 5 depicts the arc-plug flashpoint system in use in a typical configuration of the preferred embodiment of the present invention for example in a desalinization configuration showing the end to end components comprising the entire system.

A DETAILED DESCRIPTION OF THE DRAWINGS

[0061] FIG. 1 depicts arc-plug example (100) and the anode (thin wire) of the arc-plug system example (101), depicting the screw threads (102) of the arc-plug assembly, the Floating Cathode (103), and the ceramic insulator (104) in both the side and bottom (end) views as might be found in the preferred embodiment of the present invention.

[0062] FIG. 2 depicts the Crucible (200), the neodymium magnet array (201) attached to the stepper motor and mount (211) right below the combustion region (202) of the stainless steel crucible (208) shrouded in a ceramic type encasement (209) further depicting the water intake port (203) and the water outlet port (210) the most typical water (aqueous levels) (207), the arc-plug assembly itself (204) comprising the Tungsten Anode (206) and the ceramic insulator (205) as might be found in the preferred embodiment of the present invention for example.

[0063] FIG. 3 depicts the End to End System Components (300) further depicting the raw water or aqueous solution IN Port (301), the Hot Water Output Port (302), the separation wall (303), the water pump (308) Input Port (304), the Vacuum Pump Water Output Port (305), the expected water level (306), the Output Water Filter (307), the rubber shielded hoses from the Crucible (309) to the pumps, and the Crucible Output Port (310), the Ceramic outer encasement (311), the D.C. Power supply (312), the internal Stainless Steel Crucible (313), the Cathode Wire from the power supply to the Stainless Steel Crucible (314), the Crucible Water Input Port (315), the Anode Wire from the D.C. Power Supply (316), and the rotating magnet(S) assembly (317), as might be found in the preferred embodiment of the present invention for example.

[0064] FIG. 4 depicts the Magnet Configuration Detail (400), further depicting the top view of the Rotating Neodymium Magnet Assembly (404), the side view of the assembly (Sealed Unit) (403), comprising the Stepper Motor (401), the support table (402), and the Neodymium Magnet(S) (404), as might be found in the preferred embodiment of the present invention for example.

[0065] FIG. 5 depicts a 1,000 Gallon Desalinization Tank (500), comprising the Arc-Plug Assembly (501), further comprising the Anode (502), the ionic mass steering magnets (503), the Siphon Pump (504), the Bladder part (505), the Pure Water (506) being released form said Bladder, the Pure Potable Water Output Port (507), the Non-Potable Water Input Port (508), and the Magnetic (Electromagnetic) Separation Channels (510), as might be found in the preferred embodiment of the present invention for example.