Systems and methods for recovering energy from waste heat are provided. The system includes a waste heat exchanger coupled to a source of waste heat to heat a first flow of a working fluid. The system also includes a first expansion device that receives the first flow from the waste heat exchanger a
Systems and methods for recovering energy from waste heat are provided. The system includes a waste heat exchanger coupled to a source of waste heat to heat a first flow of a working fluid. The system also includes a first expansion device that receives the first flow from the waste heat exchanger and expands it to rotate a shaft. The system further includes a first recuperator coupled to the first expansion device and to receive the first flow therefrom and to transfer heat from the first flow to a second flow of the working fluid. The system also includes a second expansion device that receives the second flow from the first recuperator, and a second recuperator fluidly coupled to the second expansion device to receive the second flow therefrom and transfer heat from the second flow to a combined flow of the first and second flows.
대표청구항▼
1. A heat engine for recovering waste heat energy, comprising: a waste heat exchanger thermally coupled to a source of waste heat and configured to heat a first flow of a working fluid;a first expansion device configured to receive the first flow from the waste heat exchanger and to expand the first
1. A heat engine for recovering waste heat energy, comprising: a waste heat exchanger thermally coupled to a source of waste heat and configured to heat a first flow of a working fluid;a first expansion device configured to receive the first flow from the waste heat exchanger and to expand the first flow;a first recuperator fluidly coupled to the first expansion device and configured to receive the first flow therefrom and to transfer heat from the first flow to a second flow of the working fluid;a second expansion device configured to receive the second flow from the first recuperator and to expand the second flow; anda second recuperator fluidly coupled to the second expansion device and configured to receive the second flow therefrom and to transfer heat from the second flow to a combined flow of the first and second flows of the working fluid. 2. The heat engine of claim 1, further comprising a condenser and a pump, the condenser and the pump being positioned upstream from the second recuperator and configured to provide the combined flow thereto. 3. The heat engine of claim 2, wherein the condenser is positioned downstream from the first and second recuperators, and the first and second flows are combined to form the combined flow of working fluid upstream from the condenser. 4. The heat engine of claim 2, wherein the second expansion device is configured to drive the pump. 5. The heat engine of claim 4, further comprising a starter pump positioned downstream from the condenser and upstream from the second recuperator. 6. The heat engine of claim 2, further comprising a mass management system to control a working fluid pressure at the pump. 7. The heat engine of claim 2, further comprising a working fluid reservoir connected to a first point between the waste heat exchangers and the first expansion device, and to a second point downstream from the condenser and upstream of the pump. 8. The heat engine of claim 2, further comprising a working fluid chilling system configured to draw and compress the working fluid from upstream of the pump, and to deliver the working fluid to the condenser. 9. The heat engine of claim 1, wherein the working fluid is carbon dioxide that is in the supercritical state in at least one point in the heat engine system. 10. The heat engine of claim 1, wherein the first and second recuperators are arranged in series downstream from the first expansion device. 11. The heat engine of claim 10, wherein the second expansion device receives working fluid from a pump, through the first and second recuperators. 12. A heat engine system, comprising: one or more waste heat exchangers thermally coupled to a source of waste heat, the one or more waste heat exchangers being configured to heat a first flow of working fluid;a power turbine fluidly coupled to the one or more waste heat exchangers, the power turbine being configured to receive the first flow from the one or more waste heat expanders and to expand the first flow;a first recuperator fluidly coupled to the power turbine, the first recuperator being configured to receive the first flow from the power turbine and to transfer heat from the first flow to a second flow of working fluid;a second turbine fluidly coupled to the first recuperator, the second turbine being configured to receive the second flow from the first recuperator and to expand the second flow;a second recuperator fluidly coupled to the second turbine, the second recuperator being configured to receive the second flow of working fluid from the second turbine and to transfer heat from the second flow to a combined flow of the first and second flows of the working fluid;a condenser fluidly coupled to the first and second recuperators, the condenser being configured to receive the first and second flows from the first and second recuperators, respectively, as the combined flow and to at least partially condense the combined flow; anda pump fluidly coupled to the condenser and to the second recuperator, the pump being configured to receive the combined flow from the condenser and pump the combined flow into the second recuperator. 13. The heat engine system of claim 12, wherein the second recuperator is fluidly coupled to the one or more waste heat exchangers and to the first recuperator, wherein the first and second flows are separated downstream from the second recuperator, such that the first flow is introduced to the one or more waste heat exchangers and the second flow is introduced to the first recuperator. 14. The heat engine system of claim 12, wherein the second turbine includes a drive turbine coupled to the pump, to drive the pump. 15. The heat engine system of claim 14, further comprising a motor/generator coupled to the pump, to provide a fraction of the driving force to the pump, to convert excess power from the drive turbine to electricity, or both. 16. The heat engine system of claim 12, further comprising a plurality of valves, at least one of the plurality of valves being configured, when opened, to direct the first flow to bypass the first expansion device, and at least one of the plurality of valves being configured, when opened, to direct the working fluid to bypass the first expansion device and the first recuperator. 17. The heat engine system of claim 16, wherein the plurality of valves further includes at least one valve configured to control the mass flow of the second flow of the working fluid. 18. A method for extracting energy from a waste heat, comprising: transferring heat from the waste heat to a first flow of working fluid in a heat exchanger;expanding the first flow in a first expander to rotate a shaft;transferring heat from the first flow to a second flow of working fluid in a first recuperator;expanding the second flow in a second expansion device to rotate a shaft;transferring heat from the second flow to at least one of the first and second flows in a second recuperator;at least partially condensing the first and second flows with one or more condensers; andpumping the first and second flows with a pump. 19. The method of claim 18, further comprising combining first and second flows prior to condensing, to provide a combined flow to the condenser. 20. The method of claim 19, wherein expanding the second flow in the second expansion device to rotate the shaft further comprises driving the pump. 21. A heat engine system, comprising: a working fluid circuit configured to flow a working fluid therethrough and comprising: a pump configured to circulate the working fluid through the working fluid circuit, wherein the working fluid is split into a first portion and a second portion downstream of the pump;a first loop comprising a waste heat exchanger configured to transfer heat from waste heat to the first portion of the working fluid, a first expansion device configured to expand the first portion of the working fluid, and a first recuperator downstream of the first expansion device and configured to transfer heat from the first portion of the working fluid to the second portion of the working fluid; anda second loop comprising the first recuperator, a second expansion device disposed downstream of the first recuperator and configured to expand the second portion of the working fluid, and a second recuperator configured to transfer heat from the second portion of the working fluid to at least one of the first portion and the second portion of the working fluid downstream of the pump. 22. The heat engine system of claim 21, wherein the working fluid circuit comprises a condenser downstream of the first recuperator and the second recuperator and configured to receive a combined flow of the first portion and the second portion of the working fluid.
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