Pumped thermal electricity storage with supercritical CO2 cycles and solar heat input

Pumped Thermal Electricity Storage (PTES) is an energy storage device that uses grid electricity to drive a heat pump that generates hot and cold storage reservoirs. This thermal potential is later used to power a heat engine and return electricity to the grid. In this article, a PTES variant that u...

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Hauptverfasser:	McTigue, Joshua, Farres-Antunez, Pau, Ellingwood, Kevin, Neises, Ty, White, Alexander
Format:	Tagungsbericht
Sprache:	eng
Schlagworte:	Carbon dioxide Cold storage Compressing Electric energy storage Electricity Electricity pricing Energy storage Heat engines Heat pumps Ideal gas Reservoir storage Storage temperature Temperature gradients Working fluids
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creator	McTigue, Joshua Farres-Antunez, Pau Ellingwood, Kevin Neises, Ty White, Alexander
description	Pumped Thermal Electricity Storage (PTES) is an energy storage device that uses grid electricity to drive a heat pump that generates hot and cold storage reservoirs. This thermal potential is later used to power a heat engine and return electricity to the grid. In this article, a PTES variant that uses supercritical carbon dioxide (sCO2) as the working fluid is introduced. sCO2-PTES cycles have higher work ratios and power densities than the systems based on ideal gases that have been investigated to date. Furthermore, sCO2− PTES cycles may achieve higher round-trip efficiencies for a given hot storage temperature (up to 78% at 560°C). The sensitivity of PTES cycles to loss factors such as isentropic efficiencies and temperature differences between the power cycle and storage fluid is investigated. A second concept whereby an sCO2− PTES cycle is integrated with concentrating solar power (CSP) is introduced. This concept ‘time-shifts’ the recompression of an sCO2 recompression cycle to a period of lower electricity prices and stores the heat. When solar heat is dispatched, the recompressor may be avoided as the required heat is obtained from storage, thereby leading to increased heat engine efficiencies. The net work output of this integrated system is 10-18% greater than the conventional recompression cycle. Combining PTES with a CSP power cycle is therefore shown to improve the dispatch of solar heat as well as providing electricity storage services.
doi_str_mv	10.1063/5.0032337
format	Conference Proceeding
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This thermal potential is later used to power a heat engine and return electricity to the grid. In this article, a PTES variant that uses supercritical carbon dioxide (sCO2) as the working fluid is introduced. sCO2-PTES cycles have higher work ratios and power densities than the systems based on ideal gases that have been investigated to date. Furthermore, sCO2− PTES cycles may achieve higher round-trip efficiencies for a given hot storage temperature (up to 78% at 560°C). The sensitivity of PTES cycles to loss factors such as isentropic efficiencies and temperature differences between the power cycle and storage fluid is investigated. A second concept whereby an sCO2− PTES cycle is integrated with concentrating solar power (CSP) is introduced. This concept ‘time-shifts’ the recompression of an sCO2 recompression cycle to a period of lower electricity prices and stores the heat. When solar heat is dispatched, the recompressor may be avoided as the required heat is obtained from storage, thereby leading to increased heat engine efficiencies. The net work output of this integrated system is 10-18% greater than the conventional recompression cycle. 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When solar heat is dispatched, the recompressor may be avoided as the required heat is obtained from storage, thereby leading to increased heat engine efficiencies. The net work output of this integrated system is 10-18% greater than the conventional recompression cycle. 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When solar heat is dispatched, the recompressor may be avoided as the required heat is obtained from storage, thereby leading to increased heat engine efficiencies. The net work output of this integrated system is 10-18% greater than the conventional recompression cycle. Combining PTES with a CSP power cycle is therefore shown to improve the dispatch of solar heat as well as providing electricity storage services.</abstract><cop>Melville</cop><pub>American Institute of Physics</pub><doi>10.1063/5.0032337</doi><tpages>11</tpages><oa>free_for_read</oa></addata></record>
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source	AIP Journals Complete
subjects	Carbon dioxide Cold storage Compressing Electric energy storage Electricity Electricity pricing Energy storage Heat engines Heat pumps Ideal gas Reservoir storage Storage temperature Temperature gradients Working fluids
title	Pumped thermal electricity storage with supercritical CO2 cycles and solar heat input
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