Methods of hot and cold side charging in thermal energy storage systems
First Claim
Patent Images
1. A method comprising:
- operating a pumped thermal system in a charging mode, wherein the pumped thermal system is configured to operate in the charging mode in which energy is stored in the pumped thermal system and a discharging mode in which energy is discharged from the pumped thermal system, wherein the pumped thermal system comprises;
a compressor,a hot side heat exchanger,a hot thermal storage (“
HTS”
) medium,a turbine,a cold side heat exchanger,a cold thermal storage (“
CTS”
) medium,a working fluid, anda closed cycle fluid path configured to circulate a working fluid through, in sequence and in the same direction, the compressor, the hot side heat exchanger and in thermal contact with the HTS medium, the turbine, and the cold side heat exchanger and in thermal contact with the CTS medium when the pumped thermal system operates in the charging mode and when the pumped thermal system operates in the discharging mode; and
adding thermal energy from an external thermal energy source to the HTS medium.
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Abstract
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.
212 Citations
21 Claims
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1. A method comprising:
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operating a pumped thermal system in a charging mode, wherein the pumped thermal system is configured to operate in the charging mode in which energy is stored in the pumped thermal system and a discharging mode in which energy is discharged from the pumped thermal system, wherein the pumped thermal system comprises; a compressor, a hot side heat exchanger, a hot thermal storage (“
HTS”
) medium,a turbine, a cold side heat exchanger, a cold thermal storage (“
CTS”
) medium,a working fluid, and a closed cycle fluid path configured to circulate a working fluid through, in sequence and in the same direction, the compressor, the hot side heat exchanger and in thermal contact with the HTS medium, the turbine, and the cold side heat exchanger and in thermal contact with the CTS medium when the pumped thermal system operates in the charging mode and when the pumped thermal system operates in the discharging mode; and adding thermal energy from an external thermal energy source to the HTS medium. - View Dependent Claims (2, 3, 4, 5, 6)
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7. A method comprising:
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storing a cold thermal storage (“
CTS”
) medium inside a first cold storage tank at a first temperature above an ambient temperature of atmospheric air;pre-cooling the CTS medium below the first temperature via heat exchange with the atmospheric air; cooling the CTS medium from the ambient temperature to a second temperature below the ambient temperature by flowing the CTS medium from the first cold storage tank through a cold side heat exchanger within which the CTS medium exchanges heat with a working fluid, wherein the working fluid circulates through a pumped thermal system, wherein the pumped thermal system is configured to operate in a refrigerator cycle in which energy is stored in the pumped thermal system and a heat engine cycle in which energy is discharged from the pumped thermal system, wherein the pumped thermal system comprises a closed cycle comprising, in sequence, a compressor, a hot side heat exchanger, a turbine, and the cold side heat exchanger, and wherein the working fluid flows through, in sequence and in the same direction, the compressor, the hot side heat exchanger, the turbine, and the cold side heat exchanger when the pumped thermal system operates in the refrigerator cycle and when the pumped thermal system operates in the heat engine cycle; and storing the CTS medium in a second cold storage tank. - View Dependent Claims (8)
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9. A method comprising:
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storing a hot thermal storage (“
HTS”
) medium inside a first hot storage tank at a first temperature;pre-heating the HTS medium from the first temperature to an intermediate temperature by flowing the HTS medium through a first heat exchanger, wherein the HTS medium exchanges heat with an intermediate thermal storage (“
ITS”
) medium flowing through the first heat exchanger;heating the HTS medium from the intermediate temperature to a second temperature by flowing the HTS medium from the first heat exchanger through an element configured to transfer external thermal energy to the HTS medium; storing the HTS medium in a second hot storage tank; circulating a working fluid through, in sequence, a compressor, a hot side heat exchanger, a turbine, and a cold side heat exchanger, wherein the working fluid circulates through a pumped thermal system that is configured to operate in a charging mode in which energy is stored in the pumped thermal system and a discharging mode in which energy is discharged from the pumped thermal system, and wherein the working fluid flows through, in sequence and in the same direction, the compressor, the hot side heat exchanger, the turbine, and the cold side heat exchanger when the pumped thermal system operates in the charging mode and when the pumped thermal system operates in the discharging mode. - View Dependent Claims (10, 11, 12, 13)
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14. A method comprising:
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in a closed cycle fluid path of a pumped thermal system configured to operate in a charging mode in which energy is stored in the pumped thermal system and a discharging mode in which energy is discharged from the pumped thermal system, circulating a working fluid through, in sequence and in the same direction, a compressor, a hot side heat exchanger, a turbine, a cold side heat exchanger when the pumped thermal system operates in the charging mode and when the pumped thermal system operates in the discharging mode; and circulating an intermediate thermal storage (“
ITS”
) medium through a thermal bath and the hot side heat exchanger, wherein the ITS medium exchanges heat with the working fluid within the hot side heat exchanger, and wherein the ITS medium exchanges heat with a heat sink medium within the thermal bath. - View Dependent Claims (15, 16, 17)
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18. A method comprising:
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in a closed cycle fluid path of a pumped thermal system configured to operate in a charging mode in which energy is stored in the pumped thermal system and a discharging mode in which energy is discharged from the pumped thermal system, circulating a working fluid through, in sequence and in the same direction, a compressor, a hot side heat exchanger, a turbine, a cold side heat exchanger when the pumped thermal system operates in the charging mode and when the pumped thermal system operates in the discharging mode; and circulating an intermediate thermal storage (“
ITS”
) medium through a thermal bath and the cold side heat exchanger, wherein the ITS medium exchanges heat with the working fluid within the cold side heat exchanger, and wherein the ITS medium exchanges heat with a heat sink medium within the thermal bath. - View Dependent Claims (19, 20, 21)
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Specification
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Current AssigneeMalta, Inc.
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Original AssigneeMalta, Inc.
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InventorsLaughlin, Robert B., Larochelle, Philippe, Cizek, Nicholas
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Primary Examiner(s)Dounis, Laert
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Application NumberUS15/440,289Publication NumberTime in Patent Office964 DaysField of Search60659US Class CurrentCPC Class CodesF01K 13/02 Controlling, e.g. stopping ...F01K 3/00 Plants characterised by the...F01K 3/12 having two or more accumula...F01K 3/185 using waste heat from outsi...F01K 3/20 with heating by combustion ...F02C 1/10 Closed cyclesF02C 6/14 Gas-turbine plants having m...F05D 2250/90 Variable geometryF24S 60/10 using latent heatF28D 15/00 Heat-exchange apparatus wit...F28D 20/00 Heat storage plants or appa...F28D 2020/0047 using molten salts or liqui...Y02E 10/40 Solar thermal energy, e.g. ...Y02E 20/14 Combined heat and power gen...Y02E 20/16 Combined cycle power plant ...Y02E 60/14 Thermal energy storageY02E 60/16 Mechanical energy storage, ...
