Patent Number: 
Section: claims

1. A self-regulating inherently safe apparatus for generating neutrons, the apparatus comprising:a reaction chamber filled with a liquid fissionable material, the reaction chamber sized and shaped to provide a volumetric fill ratio for the liquid fissionable material that sustains neutron generation when the liquid fissionable material is below a selected temperature;an expansion chamber for receiving liquid fissionable material from the reaction chamber in response to expansion of the liquid fissionable material when the liquid fissionable material is above the selected temperature;wherein the expansion chamber is shaped to reduce the volumetric fill ratio of the liquid fissionable material and thereby dampen neutron generation from the liquid fissionable material in response to non-evaporative expansion of the liquid fissionable material into the expansion chamber when the liquid fissionable material is above the selected temperature;a drainage tube for draining liquid fissionable material from the reaction chamber into a storage vessel;a displacement gas pump configured to pressurize the storage vessel with a displacement gas and maintain liquid fissionable material within the reaction chamber; anda leakage channel for leaking the displacement gas from the storage vessel and thereby cause the liquid fissionable material to flow into the storage vessel when the storage vessel is no longer pressurized by the pump. 2. The apparatus of claim 1, wherein the liquid fissionable material comprises non-weapons grade plutonium. 3. The apparatus of claim 2, further comprising a reactor temperature controller configured to maintain the reaction chamber at a minimum operating temperature. 4. The apparatus of claim 1, wherein the shape and volume of the reaction chamber and the expansion chamber are selected to reduce neutron generation for temperatures above a selected operating temperature. 5. The apparatus of claim 1, wherein the storage vessel is shaped to provide a volumetric fill ratio for the liquid fissionable material that substantially inhibits neutron generation when the liquid fissionable material is contained therein. 6. The apparatus of claim 5, further comprising a reaction rate controller configured to control a neutron generation rate from liquid fissionable material contained within the reaction chamber by adjusting the pressure of the displacement gas within the storage vessel via the displacement gas pump. 7. The apparatus of claim 5, further comprising a storage vessel heater configured to heat liquid fissionable material contained within the storage vessel. 8. The apparatus of claim 1, further comprising a sub-critical collection of fissionable material proximate to the reaction chamber, the sub-critical collection of fissionable material configured to support a non-sustaining plurality of fission events per neutron received from the reaction chamber. 9. The apparatus of claim 8, wherein the sub-critical collection comprises a plurality of stacked disks of alternating diameters. 10. The apparatus of claim 8, wherein the sub-critical collection of fissionable material comprises materials previously used in a nuclear reactor. 11. A system for extracting energy from fissionable material, the system comprising:a reaction vessel comprising:a reaction chamber filled with a liquid fissionable material comprising non-weapons grade plutonium, the reaction chamber sized and shaped to sustain neutron generation when the liquid fissionable material is below a selected temperature,an expansion chamber for receiving liquid fissionable material from the reaction chamber in response to expansion of the liquid fissionable material when the liquid fissionable material is above the selected temperature,wherein the expansion chamber is shaped to reduce the volumetric fill ratio of the liquid fissionable material and thereby dampen neutron generation from the liquid fissionable material without external or active control in response to non-evaporative expansion of the liquid fissionable material into the expansion chamber when the liquid fissionable material is above the selected temperature;a drainage tube for draining liquid fissionable material from the reaction chamber into a storage vessel;a displacement gas pump configured to pressurize the storage vessel with a displacement gas and maintain liquid fissionable material within the reaction chamber; anda leakage channel for leaking the displacement gas from the storage vessel and thereby cause the liquid fissionable material to flow into the storage vessel when the storage vessel is no longer pressurized by the pump; anda sub-critical collection of fissionable material proximate to the reaction chamber, the sub-critical collection of fissionable material configured to support a non-sustaining plurality of fission events from neutrons received from the reaction chamber.