초록 ▼

The present disclosure provides pumped thermal energy storage systems that can be used to store electrical energy. A pumped thermal energy storage system of the present disclosure can store energy by operating as a heat pump or refrigerator, whereby net work input can be used to transfer heat from t

The present disclosure provides pumped thermal energy storage systems that can be used to store electrical energy. A pumped thermal energy storage system of the present disclosure can store energy by operating as a heat pump or refrigerator, whereby net work input can be used to transfer heat from the cold side to the hot side. A working fluid of the system is capable of efficient heat exchange with heat storage fluids on a hot side of the system and on a cold side of the system. The system can extract energy by operating as a heat engine transferring heat from the hot side to the cold side, which can result in net work output. Systems of the present disclosure can employ solar heating for improved storage efficiency.

대표청구항 ▼

1. An energy storage and retrieval system, comprising: a compressor;a first heat storage unit;a turbine;a second heat storage unit;a working fluid that flows along a fluid flow path in a closed cycle including, in sequence, the compressor, the first heat storage unit, the turbine, and the second hea

1. An energy storage and retrieval system, comprising: a compressor;a first heat storage unit;a turbine;a second heat storage unit;a working fluid that flows along a fluid flow path in a closed cycle including, in sequence, the compressor, the first heat storage unit, the turbine, and the second heat storage unit; andan auxiliary tank comprising the working fluid, wherein the auxiliary tank is in fluid communication with the fluid flow path of the closed cycle; andwherein the system alternately operates as both (i) a heat engine to provide mechanical work from heat and (ii) as a heat pump to use mechanical work to store heat, andwherein the working fluid flows through, in sequence and in the same direction, the compressor, the first heat storage unit, the turbine, and the second heat storage unit when the apparatus operates as the heat engine and when the apparatus operates as a heat pump. 2. The system of claim 1, wherein the mechanical work provided in (i) or used in (ii) varies with an absolute pressure of the working fluid in the closed cycle. 3. The system of claim 1, wherein an absolute pressure of the working fluid in the closed cycle varies with an amount of working fluid transferred between the auxiliary tank and the closed cycle. 4. The system of claim 1, wherein the first heat storage unit and the second heat storage unit are both capable of exchanging heat with the working fluid, and wherein the first heat storage unit or the second heat storage unit comprises: a first thermal storage tank;a second thermal storage tank;a heat storage fluid capable of flowing between the first and second thermal storage tanks to store or release heat; anda counter-flow heat exchanger, wherein the heat storage fluid and the working fluid flow in opposite directions. 5. The system of claim 1, further comprising a radiator operatively coupled to the system to dissipate waste heat generated during operation of the system. 6. The system of claim 1, wherein the first and/or second heat storage unit comprises a storage fluid held at about ambient pressure. 7. The system of claim 1, wherein the auxiliary tank is in fluid communication with the closed cycle at a high pressure side of the closed cycle, which high pressure side is downstream from the compressor and upstream from the turbine, and wherein the auxiliary tank is in fluid communication with the closed cycle at a low pressure side of the closed cycle, which low pressure side is downstream from the turbine and upstream from the compressor. 8. The system of claim 7, wherein the fluid communication is regulated by a valve. 9. The system of claim 1, wherein the auxiliary tank contains the working fluid at a pressure that is between a maximum and a minimum pressure of the working fluid in the closed cycle. 10. The system of claim 4, wherein the system further comprises (i) a solar heater for heating the heat storage fluid of the first heat storage unit or the working fluid, (ii) a combustion heat source for heating the heat storage fluid of the first heat storage unit or the working fluid, or (iii) a waste heat source for heating the heat storage fluid of the first heat storage unit or the working fluid. 11. The system of claim 4, further comprising a controller that is programmed to regulate (i) a temperature difference between any two thermally coupled fluid elements of the counter-flow heat exchanger, and/or (ii) one or more fluid properties of the fluid elements of the counter-flow heat exchanger such that entropy generation in the counter-flow heat exchanger is minimized during operation of the system. 12. The system of claim 11, wherein the controller is programmed to regulate (i) and/or (ii) such that, during use, a rate of entropy generation associated with the counter-flow heat exchanger is less than 20% of a rate of entropy generation within the system. 13. A method for storing and releasing energy, the method comprising: (a) providing a system comprising a closed cycle comprising, in sequence, a compressor, a first heat storage unit, a turbine and a second heat storage unit configured to circulate a working fluid, wherein the system further comprises an auxiliary tank for the working fluid, and wherein the first and second heat storage units exchange heat with the working fluid flowing through the closed cycle; and(b) alternately and sequentially operating the system in a refrigerator mode and a heat engine mode, wherein in the refrigerator mode, mechanical work is used to transfer thermal energy from the second heat storage unit to the first heat storage unit, and wherein, in the heat engine mode, thermal energy transferred from the first heat storage unit to the second heat storage unit is used to provide mechanical work,wherein the working fluid flows through, in sequence and in the same direction, the compressor, the first heat storage unit, the turbine, and the second heat storage unit in both the refrigerator mode and the heat engine mode. 14. The method of claim 13, further comprising (i) in the refrigerator mode, storing energy at a rate of at least about 10 megawatt, or (ii) in the heat engine mode, extracting energy at a rate of at least about 10 megawatt. 15. The method of claim 13, further comprising (i) transferring more thermal energy between the second heat storage unit and the first heat storage unit by increasing an absolute pressure of the working fluid, or (ii) transferring less thermal energy between the second heat storage unit and the first heat storage unit by decreasing an absolute pressure of the working fluid. 16. A method for storing and releasing energy, the method comprising: (a) increasing the pressure of a working fluid, operating in a closed cycle comprising a fluid flow path configured to circulate the working fluid, from a first pressure to a second pressure with the aid of a compressor, thereby increasing the temperature of the working fluid;(b) using a first heat storage unit downstream of the compressor and in thermal communication with the working fluid for (i) in a storing mode, removing heat from the working fluid and decreasing the temperature of the working fluid, which decrease in temperature is at substantially the second pressure, or (ii) in a releasing mode, supplying heat to the working fluid and increasing the temperature of the working fluid, which increase in temperature is at substantially the second pressure;(c) decreasing the pressure of the working fluid from the second pressure to the first pressure with the aid of a turbine, thereby decreasing the temperature of the working fluid;(d) using a second heat storage unit downstream of the turbine and in thermal communication with the working fluid for (i) in a storing mode, supplying heat to the working fluid and increasing the temperature of the working fluid, which increase in temperature is at substantially the first pressure, or (ii) in a releasing mode, removing heat from the working fluid and decreasing the temperature of the working fluid, which decrease in temperature is at substantially the first pressure; and(e) with the aid of a recuperator in fluid communication with the fluid flow path, supplying heat to the working fluid or removing heat from the working fluid, wherein the working fluid does not undergo a phase change, wherein the working fluid flows through, in sequence, the compressor, the first heat storage unit, the recuperator, the turbine, the second heat storage unit, and the recuperator in the storing mode,wherein the working fluid flows through, in sequence, the compressor, the recuperator, the first heat storage unit, the turbine, the recuperator, and the second heat storage unit in the releasing mode, andwherein the working fluid flows in the same direction in both the storing mode and the releasing mode. 17. The method of claim 16, wherein the first heat storage unit is capable of exchanging heat with the working fluid between a first low temperature and a first high temperature, which first low temperature is lower than the first high temperature, wherein the second heat storage unit is capable of exchanging heat with the working fluid between a second low temperature and a second high temperature, which second low temperature is lower than the second high temperature, and wherein the first low temperature is higher than the second high temperature. 18. The method of claim 17, wherein (e) comprises exchanging heat with the working fluid between the first low temperature and the second high temperature using the recuperator. 19. The method of claim 18, wherein (e) further comprises transferring heat between a portion of the working fluid flowing along a high pressure portion of the closed cycle and a portion of the working fluid flowing along a low pressure portion of the closed cycle.