Patent Number: 
Section: claims

1. An apparatus for creating a chemical hydride, comprising:a pseudo-plasma-electrolysis reactor having top and bottom surfaces, and defining a cavity;an aqueous solution formed of sodium metaborate and water, and which is received in the cavity;a cathode mounted on the bottom surface of the pseudo-plasma-electrolysis reactor and submerged in the aqueous solution;an anode moveably mounted on the top surface of the pseudo-plasma-electrolysis reactor and which is operable to move into, and out of fluidic ohmic electrical contact with the aqueous solution formed of the sodium metaborate and the water; anda source of electrical power electrically coupled to the anode and the cathode, and wherein the application of the electrical power to the anode and the cathode facilitates the chemical reaction of the sodium metaborate and the water to form a chemical hydride in the solution. 2. An apparatus as claimed in claim 1, and further comprising:a nuclear reactor which has a hot gas exhaust containing heat energy;a first heat exchanger coupled in fluid flowing relation relative to the hot gas exhaust of the nuclear reactor, and the aqueous solution of sodium metaborate and water, and wherein the first heat exchanger absorbs the heat energy provided by the hot gas exhaust and transfers it to the aqueous solution of sodium metaborate and water to raise the temperature of the aqueous solution of sodium metaborate and water; anda second heat exchanger coupled in fluid flowing relation relative to the hot gas output of the nuclear reactor and which absorbs the heat energy of the hot gas output, and which transfers the heat energy, so absorbed, so as to generate the source of electrical power. 3. An apparatus as claimed in claim 2, and further comprising:a source of water coupled in fluid flowing relation relative to the second heat exchanger, and wherein the source of water, upon being exposed to the heat energy absorbed by the second heat exchanger, is converted into a source high pressure steam;a steam turbine coupled in fluid flowing relation relative to the source of steam and which, when exposed to the high pressure steam, produces a mechanical energy output; anda generator coupled to the mechanical energy output of the steam turbine and which generates the source of the electrical power. 4. An apparatus as claimed in claim 1, and wherein the electrical power generates an oxygen plasma, and wherein the chemical reaction of the sodium metaborate and the water generates oxygen gas and sodium borohydride in the aqueous solution. 5. An apparatus as claimed in claim 1, and wherein the anode is moved into fluidic, ohmic electrical contact with the aqueous solution, and is then energized by supplying the electrical power to both the anode and the cathode, and wherein an electrical current is established in the aqueous solution, and which facilitates an initial electrolysis of the aqueous solution, and wherein following the energizing of the anode and cathode which facilitates the electrolysis, the anode is moved out of fluidic, ohmic electrical contact with the aqueous solution to form a plasma which enhances the chemical reaction of sodium metaborate and the water to form the chemical hydride. 6. An apparatus as claimed in claim 5, and wherein, the plasma comprises an oxygen plasma, and the chemical hydride comprises sodium borohydride. 7. An apparatus for creating a chemical hydride, comprising:a pseudo-plasma-electrolysis reactor having top and bottom surfaces and defining a cavity;an aqueous solution of sodium metaborate and water received within the cavity of the pseudo-plasma-electrolysis reactor;a cathode fixedly mounted on the bottom surface of the pseudo-plasma-electrolysis reactor and which is disposed in fluidic, ohmic electrical contact with the aqueous solution;an anode moveably mounted on the top surface of the pseudo-plasma-electrolysis reactor and which selectively moves into, and out of fluidic, ohmic electrical contact with the aqueous solution;a nuclear reactor which has a hot gas exhaust which provides heat energy;a first heat exchanger coupled in fluid flowing relation relative to the hot gas output and which is operable to absorb the heat energy of the hot gas exhaust flowing therethrough, and wherein the first heat exchanger is further disposed in fluid flowing relation relative to the cavity of the pseudo-plasma-electrolysis reactor, and wherein the aqueous solution flows through first heat exchanger to absorb the heat energy provided by the hot gas exhaust to increase the temperature thereof;a second heat exchanger disposed in fluid flowing relation relative to the hot gas output and which is operable to absorb the heat energy of the hot gas flowing therethrough;a source of water coupled in fluid flowing relation relative to the second heat exchanger, and wherein the source of water absorbs the heat energy previous absorbed by the second heat exchanger and is converted into a source of high pressure steam;a steam turbine coupled in fluid flowing relation relative to the second heat exchanger and which is operable to receive the source of high pressure steam and produce a mechanical energy output;a generator coupled to the mechanical energy output of the steam turbine and which generates a source of electricity which is selectively supplied to the anode and the cathode; andan actuator coupled in force transmitting relation relative to the anode and which moves the anode into and out of fluidic contact with the aqueous solution, and wherein the actuator, when energized, moves the anode into fluidic, ohmic electrical contact with the aqueous solution, and wherein following contact of the anode with the aqueous solution, the source of electricity is applied to the anode, and the cathode, to create an electrical current in the aqueous solution, and wherein the actuator is then energized to move the anode out of fluidic, ohmic electrical contact with the aqueous solution to form an oxygen plasma therebetween the anode and the aqueous solution, and wherein the formation of the plasma facilitates the chemical reaction of the sodium metaborate and water to produce oxygen gas and sodium borohydride in the aqueous solution.