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 language | English |
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Article number | 101514 |
Number of pages | 19 |
Journal | Cell Reports Physical Science |
Volume | 4 |
Issue number | 8 |
DOIs | |
Publication status | Published - 2023 |
Keywords
- distributed power
- energy transition
- H2/O2 combustion
- oxy-fuel combustion
- seasonal energy storage
- supercritical-CO2 cycle
- zero-emission power cycle
Fingerprint
Dive into the research topics of 'Thermodynamic analysis of a zero-emission combustion cycle for energy transition'. Together they form a unique fingerprint.Datasets
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HYCOS thermodynamic model underlying the publication: Thermodynamic Analysis of a Zero-Emission Combustion Cycle for Energy Transition
Dave, K. A. (Creator) & Gangoli Rao, A. (Contributor), TU Delft - 4TU.ResearchData, 21 Jul 2023
DOI: 10.4121/d8887792-0e15-4f41-8263-875927562371
Dataset/Software: Dataset
Prizes
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Best TU Delft H2 Platform paper
Dave, K.A. (Recipient), 19 Mar 2024
Prize: Prize (including medals and awards)
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NVV Combustion Award 2021 for MSc thesis titled "Feasibility Analysis of Internally Fired s-CO2 Cycle for Energy Transition"
Dave, K.A. (Recipient), Oct 2021
Prize: National/international honour