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An electrolytic reactor and related methods are provided for supplementing the air-intake of an internal combustion engine with hydrogen. In one embodiment, the reactor has a core defined by a plurality of whole metal plates separated by peripheral gaskets; an inlet for providing an electrolyte to t

An electrolytic reactor and related methods are provided for supplementing the air-intake of an internal combustion engine with hydrogen. In one embodiment, the reactor has a core defined by a plurality of whole metal plates separated by peripheral gaskets; an inlet for providing an electrolyte to the core; a gas and effluent outlet, and a pump to force an electrolyte through the core.

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1. An electrolytic reactor comprising: a core defined by a plurality of whole metal plates separated by peripheral gaskets, said plurality of metal plates composed of at least one anodic metal plate and at least one cathodic metal plate;an inlet through one of said peripheral gaskets for providing a

1. An electrolytic reactor comprising: a core defined by a plurality of whole metal plates separated by peripheral gaskets, said plurality of metal plates composed of at least one anodic metal plate and at least one cathodic metal plate;an inlet through one of said peripheral gaskets for providing an electrolyte to a pocket defined between a top surface of one of said metal plates, a bottom surface of another one of said plates, and said one of said peripheral gaskets;an outlet through said one of said peripheral gaskets for gas and the electrolyte to leave said pocket; and,a pump that (a) forces the electrolyte through the inlet into the pocket and (b) forces gas and a remainder of the electrolyte through the outlet. 2. The reactor of claim 1 further comprising an electric current provided (a) between said anodic and cathodic plates at approximately 2 amperes and (b) through the electrolyte in said pocket. 3. The reactor of claim 1 wherein said one and said another one of said whole metal plates respectively feature rough top and bottom surfaces. 4. The reactor of claim 1 wherein said outlet is in fluid communication with an air-intake of an internal combustion engine. 5. The reactor of claim 1 wherein said one and said another one of said plurality of whole metal plates is disposed between said cathodic and anodic metal plates. 6. The reactor of claim 1 wherein water is provided to the reactor as the electrolyte. 7. The reactor of claim 1 further comprising: Wherein said inlet and outlet define cooperating ducts through said pocket; and,a sealant around the ducts whereby the electrolyte does not contact said one and said another one of said plurality of metal plates unless said electrolyte is within said pocket. 8. The reactor of claim 1 wherein said one and said another one of said metal plates are disposed between anodic and cathodic metal plates. 9. An automobile comprising: an internal combustion engine with an air-intake;an electrolyte reservoir;a gas reservoir in fluid communication with said air-intake;an electrolytic reactor comprising a core with at least one pocket defined between a bottom surface of a first metal plate, a top surface of a second metal plate, and a peripheral gasket between said first and metal platesan amount of electrolyte from said electrolyte reservoir disposed in said at least one pocket, said amount of electrolyte only in contact with one of said top surface, said bottom surface, or said gasket,an electric current passing through the pocket from the bottom surface to the top surface so that a portion of said amount of electrolyte is converted to an amount of gas,an inlet to the pocket that is in fluid communication with the electrolyte reservoir, said inlet for providing said amount of electrolyte to the pocket,an outlet from the pocket that is in fluid communication with the electrolyte reservoir and the gas reservoir, said outlet for providing said amount of gas to the gas reservoir and for providing said amount of electrolyte, less said portion of electrolyte, to the electrolyte reservoir; and,a pump that delivers (a) said amount of electrolyte to the pocket via the inlet, (b) said amount of gas to the gas reservoir, and (c) said amount of electrolyte, less said portion of electrolyte, to the electrolyte reservoir. 10. The automobile of claim 9 wherein said electric current is low amperage. 11. The automobile of claim 9 wherein said top and bottom surfaces are rough surfaces. 12. The automobile of claim 9 wherein said amount of gas is directed to said air-intake from said gas reservior. 13. The automobile of claim 9 wherein said electric current is generated by at least three cathodes and two anodes. 14. The automobile of claim 9 featuring a schedule for providing fresh electrolyte to the electrolyte reservoir that is similar in timing to a schedule for changing the oil of said internal combustion engine. 15. The automobile of claim 9 wherein said inlet and said outlet define cooperating ducts through said gaskets. 16. The automobile of claim 9 wherein water plus KOH is provided to the reactor as the amount of electrolyte. 17. A method of charging an internal combustion engine comprising the steps of: forcefully passing an electrolyte between first and second whole metal plates separated by a peripheral gasket so that (a) the only portion of the first metal plate that is contacted by the electrolyte is a top surface thereof and (b) the only portion of the second metal plate that is contacted by the electrolyte is a bottom surface thereof;passing an electric current from the first whole metal plate to said second whole metal plate, said electric current passing through said electrolyte;directing any resultant hydrogen to an air-intake of said internal combustion engine. 18. The method of claim 17 wherein said top and bottom surfaces are rough surfaces. 19. The method of claim 17 wherein the steps are simultaneously accomplished at differing locations within an electrolytic reactor. 20. The method of claim 17 wherein said electrolyte is water or water plus KOH. 21. A heat-exchanger comprising: a plurality of pockets, said pockets each defined by a top surface of a whole metal plate, a bottom surface of another whole metal plate, and a peripheral gasket disposed between said whole metal plates;cooperating ducts through each of said peripheral gaskets;a means for generating heat in said metal plates via passing electricity through said pockets;an electrolyte heat transfer medium; and,a means for forcing said electrolyte through said pocket via said cooperating ducts, wherein the only components of said whole metal plates that are contacted by the electrolyte are said top and bottom surfaces. 22. A core of an electrolytic reactor comprising: a plurality of pockets, said pockets each defined by a top surface of a whole metal plate, a bottom surface of another whole metal plate, and a peripheral gasket disposed between said whole metal plates;wherein at least one of said pocket is connected to an anode at one of said component plates; and,wherein at least one of said pockets is connected to a cathode at one of said component plates. 23. An electrolytic pocket comprising: two whole metal plates separated by a peripheral gasket between a top surface of one of said two whole metal plates and a bottom surface of the other of said two hole metal plates, wherein a pocket is defined, said pocket consisting of (1) the top surface of one of said two whole metal plates, (2) the bottom surface of the other of said two whole metal plates, and (3) the peripheral gasket; and,cooperating ducts through said peripheral gasket.