The potential of metal hydrides paired with compressed hydrogen as thermal energy storage for concentrating solar power plants
Autor: | Craig E. Buckley, Drew A. Sheppard |
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Rok vydání: | 2019 |
Předmět: |
Materials science
Hydrogen Hydrogen compressor Nuclear engineering Energy Engineering and Power Technology chemistry.chemical_element 02 engineering and technology 010402 general chemistry Thermal energy storage 7. Clean energy 01 natural sciences Molten salt Solar power Compressed hydrogen Renewable Energy Sustainability and the Environment business.industry Hydride 021001 nanoscience & nanotechnology Condensed Matter Physics 0104 chemical sciences Fuel Technology chemistry 13. Climate action 0210 nano-technology Underground hydrogen storage business |
Zdroj: | International Journal of Hydrogen Energy. 44:9143-9163 |
ISSN: | 0360-3199 |
Popis: | Concentrating solar power (CSP) plants require thermal energy storage (TES) systems to produce electricity during the night and periods of cloud cover. The high energy density of high-temperature metal hydrides (HTMHs) compared to state-of-the-art two-tank molten salt systems has recently promoted their investigation as TES systems. A common challenge associated with high-temperature metal hydride thermal energy storage systems (HTMH TES systems) is storing the hydrogen gas until it is required by the HTMH to generate heat. Low-temperature metal hydrides can be used to store the hydrogen but can comprise a significant proportion of the overall system cost and they also require thermal management, which increases the engineering complexity. In this work, the potential of using a hydrogen compressor and large-scale underground hydrogen gas storage using either salt caverns or lined rock caverns has been assessed for a number of magnesium- and sodium-based hydrides: MgH2, Mg2FeH6, NaMgH3, NaMgH2F and NaH. Previous work has assumed that the sensible heat of the hydrogen released from the HTMH would be stored in a small, inexpensive regenerative material system. However, we show that storing the sensible heat of the hydrogen released would add between US$3.6 and US$7.5/kWhth to the total system cost for HTMHs operating at 565 °C. If the sensible heat of released hydrogen is instead exploited to perform work then there is a flow-on cost reduction for each component of the system. The HTMHs combined with underground hydrogen storage all have specific installed costs that range between US$13.7 and US$26.7/kWhth which is less than that for current state-of-the-art molten salt heat storage. Systems based on the HTMHs Mg2FeH6 or NaH have the most near term and long term potential to meet SunShot cost targets for CSP thermal energy storage. Increasing the operating temperature and hydrogen equilibrium pressure of the HTMH is the most effective means to reduce costs further. |
Databáze: | OpenAIRE |
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