Thermodynamic analysis of a zero-emission combustion cycle for energy transition

Kaushal Dave, Arvind Gangoli Rao*

*Corresponding author for this work

Research output: Contribution to journalArticleScientificpeer-review

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Abstract

The power sector accounts for ∼40% of global energy-related CO2 emissions. Its decarbonization by switching to low-carbon renewables is essential for a sustainable future. Existing electrical grids, however, have limited capacity to absorb the variability introduced by these new energy sources and rely largely on natural-gas-based power generation. For deep decarbonization, alternative solutions to increase grid flexibility are needed. Among these, energy storage is expected to have a key role. This paper proposes a unique energy storage and re-conversion system by coupling the hydrogen combustion in supercritical CO2 (HYCOS) cycle, a zero-emission combustion cycle, with long-term/seasonal energy storage based on green H2 production. This power cycle is expected to be highly scalable and compact and can deliver power at net electrical efficiency between 55% and 60% at distributed generation levels. Thus, it can be highly competitive with existing solutions such as fuel cells, reciprocating engines, and gas turbines.

Original languageEnglish
Article number101514
Number of pages19
JournalCell Reports Physical Science
Volume4
Issue number8
DOIs
Publication statusPublished - 2023

Keywords

  • distributed power
  • energy transition
  • H2/O2 combustion
  • oxy-fuel combustion
  • seasonal energy storage
  • supercritical-CO2 cycle
  • zero-emission power cycle

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