Design-Point Techno-Economics of Brayton Cycle PTES for Combined Heat and Power: Paper No. GT2024-128039

Ty Neises, Joshua McTigue

Research output: Contribution to conferencePaper

Abstract

Pumped thermal energy storage (PTES) systems are grid batteries that use heat pumps to create both hot and cold thermal energy stores when there is excess electricity and then use a power cycle to convert the thermal energy into electricity when there is demand for electricity. In normal operation, Joule-Brayton PTES discharges low-grade heat at temperatures useful for thermal energy consumers like district and industrial heating. Furthermore, PTES designs, like conventional combined heat and power (CHP) technology, can be modified to sacrifice some round-trip efficiency RTE to increase the temperature of heat rejection. This paper uses design-point performance and cost models that provide a detailed understanding of the efficiency and cost trade-offs of rejecting heat at various temperatures in ideal-gas Brayton PTES configurations. First, we keep the heat rejection in its nominal location in the PTES system: in the discharge cycle after the low-pressure exit of the recuperator before the cold-storage heat exchanger. Next, we move the heat rejection to the discharge turbine exit. We define design-point metrics that isolate both the cost and performance penalty associated with the hotter heat rejection and attribute it exclusively to the heat economic metrics. Finally, we estimate the performance of electric heater technology to generate heat at equivalent temperatures. We find that the levelized cost of heat, including the cost of thermal energy storage (TES) buffering the PTES and heat off-taker, compares favorable versus electric technologies and is less than the cost of natural gas for low temperature scenarios and competitive with the cost of natural gas in some regions of the contiguous United States in high temperature scenarios.
Original languageAmerican English
Number of pages12
DOIs
StatePublished - 2024
EventASME Turbo Expo 2024 - London, UK
Duration: 24 Jun 202428 Jun 2024

Conference

ConferenceASME Turbo Expo 2024
CityLondon, UK
Period24/06/2428/06/24

NREL Publication Number

  • NREL/CP-5700-88504

Keywords

  • CHP
  • process heat
  • PTES

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