Patent Number: 
Section: claims

1. An autonomous self-powered system for cooling radioactive materials, the system comprising:a pool of liquid including radioactive materials comprised of spent nuclear fuel immersed in the pool of liquid;a closed-loop fluid circuit comprising a working fluid having a boiling temperature that is less than a boiling temperature of the liquid of the pool, the closed-loop fluid circuit comprising, in operable fluid coupling, a hydraulic pump, an evaporative heat exchanger having a tube bundle comprising a plurality of heat exchange tubes at least partially immersed in the liquid of the pool in which an outside of the heat exchange tubes is in direct contact with the liquid of the pool, a turbogenerator, and a condenser in which the working fluid flows therebetween;the closed-loop fluid circuit converting thermal energy extracted from the liquid of the pool into electrical energy in accordance with the Rankine Cycle, the electrical energy powering the pump;wherein the working fluid flows through the tubeside of the plurality heat exchange tubes inside the heat exchange tubes and operates to absorb heat from the pool of liquid, the working fluid inside the tubes being fluidly isolated from the liquid in the pool;wherein the condenser is an induced-flow air-cooled condenser that comprises a housing defining a bottom cool air inlet, a top warmed air outlet at a top, and a blower disposed in the warm air outlet, the blower operably coupled to the air-cooled condenser to draw cool air vertically upwards through the housing from the bottom cool air inlet, over heat exchange tubes disposed in the housing below the blower, and discharge heated air through the top warmed air outlet of the housing, the working fluid being a tube-side fluid flowing vertically downwards through the heat exchange tubes of the air-cooled condenser, wherein the air flows in a first vertical direction from the bottom cool air inlet to the top warmed air outlet and the working fluid flows in a second vertical direction through the heat exchange tubes, the second vertical direction being opposite to the first vertical direction;wherein the air-cooled condenser includes a horizontal working fluid inlet header comprising a first plurality of concentrically arranged toroidal tubes and a horizontal working fluid outlet header comprising a second plurality of concentrically arranged toroidal tubes, the inlet and outlet headers spaced vertically apart in the housing and fluidly coupled to the closed-loop fluid circuit;wherein the heat exchange tubes of the air-cooled condenser are straight tubes each having a first end coupled to the toroidal tubes of the horizontal working fluid inlet header and an opposite second end coupled to the toroidal tubes of the horizontal working fluid outlet header, the heat exchange tubes each being vertically oriented and extending in a vertical direction between the horizontal working fluid inlet and outlet headers, andwherein the vapor phase of the working fluid enters the air-cooled condenser at an inlet and the liquid phase of the working fluid exits the air-cooled condenser at an outlet, wherein the inlet of the air-cooled condenser is located at a greater elevation than the outlet of the air-cooled condenser. 2. The autonomous self-powered system of claim 1 further comprising:the evaporative heat exchanger converting the working fluid from a liquid phase to a vapor phase by transferring the thermal energy from the liquid of the pool to the working fluid;the turbogenerator receiving the vapor phase of the working fluid from the evaporative heat exchanger, the turbogenerator generating the electrical energy by extracting energy from the vapor phase of the working fluid flowing through the turbogenerator;the condenser receiving the vapor phase of the working fluid from the turbogenerator and converting the vapor phase of the working fluid flowing through the condenser back into the liquid phase of the working fluid by removing thermal energy from the working fluid; andthe pump electrically coupled to the turbogenerator so as to be powered by the electrical energy generated by the turbogenerator. 3. The autonomous self-powered system of claim 1 wherein the air cooled condenser further comprises a shroud forming a cavity, the heat exchange tubes located within the cavity of the shroud, the shroud having an air inlet for introducing cool air into the cavity and an air outlet for allowing heated air to exit the cavity, the heat exchange tubes located at an elevation between an elevation of the air inlet and an elevation of the air outlet so that thermal energy transferred from the working fluid flowing to the air through the heat exchange tubes causes a natural convective air flow within the shroud. 4. The autonomous self-powered system of claim 1 wherein the pump forces a liquid phase of the working fluid into the evaporative heat exchanger. 5. The autonomous self-powered system of claim 4 further comprising a reservoir of the liquid phase of the working fluid, the closed-loop fluid circuit comprising the reservoir, and the reservoir located upstream of the hydraulic pump and downstream of the condenser. 6. The autonomous self-powered system of claim 1 wherein the pool of the liquid is at a first pressure and the working fluid within the evaporative heat exchanger is at a second pressure that is greater than the first pressure, the boiling temperature of the working fluid at the second pressure being less than the boiling temperature of the liquid of the pool at the first pressure. 7. The autonomous self-powered system of claim 6 wherein the first pressure is atmospheric and the second pressure is in a range of 250 psia to 400 psia. 8. The autonomous self-powered system of claim 1 wherein the liquid of the pool is water and the working fluid is selected from a group consisting of a refrigerant and a hydrocarbon. 9. The autonomous self-powered system of claim 1 wherein the evaporative heat exchanger is fully immersed in the liquid of the pool and located at a top portion of the pool. 10. The autonomous self-powered system of claim 1 further comprising a rechargeable electrical energy source coupled to the turbogenerator so as to be charged by the electrical energy generated by the turbogenerator. 11. The autonomous self-powered system of claim 1 wherein the evaporative heat exchanger is configured to achieve an internal thermosiphon flow of a liquid phase of the working fluid within the evaporative heat exchanger. 12. The autonomous self-powered system of claim 1 wherein the autonomous self-powered system operates free of electrical energy generated outside of the Rankine Cycle of the closed-loop fluid circuit. 13. The autonomous self-powered system of claim 1 further comprising one or more racks immersed in the pool of liquid, and wherein the radioactive materials comprise spent nuclear fuel rods supported in the one or more racks. 14. The autonomous self-powered system of claim 1 wherein the Rankine Cycle is an Organic Rankine Cycle. 15. A method of cooling a pool of liquid heated by radioactive materials comprising:flowing a working fluid having a boiling temperature that is less than a boiling temperature of the liquid of the pool through a closed-loop fluid circuit that, in accordance with the Rankine Cycle: (1) extracts thermal energy from the liquid of the pool into the working fluid; (2) converts a first portion of the extracted thermal energy into electrical energy that is used to power a hydraulic pump that forces flow of the working fluid through the closed-loop fluid circuit; and (3) transfers a second portion of the extracted thermal energy to a secondary fluid;wherein the radioactive materials are comprised of spent nuclear fuel immersed in the pool of liquid;wherein thermal energy is extracted from the liquid of the pool into the working fluid by an evaporative heat exchanger having a tube bundle comprising a plurality of heat exchange tubes at least partially immersed in the liquid in which an outside of the heat exchange tubes is in direct contact with the liquid of the pool;wherein the working fluid flows through the tubeside of the plurality heat exchange tubes inside the heat exchange tubes and operates to absorb heat from the pool of liquid, the working fluid inside the tubes being fluidly isolated from the liquid in the pool;wherein the second portion of the extracted thermal energy is transferred to air by an induced-flow air-cooled condenser;wherein the induced-flow air-cooled condenser comprises a housing defining a bottom cool air inlet, a top warmed air outlet at a top, and a blower disposed in the warm air outlet, the blower operably coupled to the air-cooled condenser to draw cool air vertically upwards through the housing from the bottom cool air inlet, over heat exchange tubes disposed in the housing below the blower, and discharge heated air through the top warmed air outlet of the housing, the working fluid being a tube-side fluid flowing vertically downwards through the heat exchange tubes of the air-cooled condenser, wherein the air flows in a first vertical direction from the bottom cool air inlet to the top warmed air outlet and the working fluid flows in a second vertical direction through the heat exchange tubes, the second vertical direction being opposite to the first vertical direction;wherein the working fluid in the air-cooled condenser flows in toroidal path via a horizontal working fluid inlet header comprising a first plurality of concentrically arranged toroidal tubes and a horizontal working fluid outlet header comprising a second plurality of concentrically arranged toroidal tubes, the inlet and outlet headers spaced vertically apart in the housing, the inlet and outlet headers fluidly coupled to closed-loop fluid circuit;wherein the heat exchange tubes of the air-cooled condenser are straight tubes each having a first end coupled to the horizontal working fluid inlet header and an opposite second end coupled to the horizontal working fluid outlet header, the heat exchange tubes each being vertically oriented and extending in a vertical direction between the horizontal working fluid inlet and outlet headers, and wherein the vapor phase of the working fluid enters the air-cooled condenser at an inlet and the liquid phase of the working fluid exits the air-cooled condenser at an outlet, wherein the inlet of the air-cooled condenser is located at a greater elevation than the outlet of the air-cooled condenser. 16. The method of claim 15 wherein the evaporative heat exchanger converts the working fluid from a liquid phase to a vapor phase, and is immersed in the liquid of the pool. 17. The method of claim 15 wherein the first portion of the extracted thermal energy is converted into the electrical energy by a turbogenerator that is electrically coupled to the pump. 18. The method of claim 15 wherein the flow of the working fluid through the closed-loop circuit is achieved independent of any electrical energy other than that generated by the Rankine Cycle of the closed-loop fluid circuit.