Ammonia Airship Cooling: An Option for Renewable Cooling in the Tropics

Hunt, J. ORCID:, Zakeri, B. ORCID:, Nascimento, A., Guo, F. ORCID:, Freitas, M.A.V., Silva, C.V., & van Ruijven, B. ORCID: (2023). Ammonia Airship Cooling: An Option for Renewable Cooling in the Tropics. Energies 17 (1) e111. 10.3390/en17010111.

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The world is warming, and the demand for cooling is increasing. Developing a future green hydrogen economy will also increase the demand for cooling for hydrogen liquefaction. This increase in cooling demand will happen mainly in tropical and developing countries due to their increase in population, improvements in quality of life, and the export of their renewable potential with liquid hydrogen. To solve this increase in demand for cooling, this paper proposes the use of ammonia airship cooling (AAC). AAC extracts cold from the tropopause (−80 °C) with airships and ammonia refrigeration cycles. The liquid ammonia is then transported back to the surface to provide low temperature cooling services (−33 °C). This cooling service is particularly interesting for lowering the electricity consumption in hydrogen liquefaction plants. If all the technological challenges mentioned in the paper are addressed, it is estimated that the cost of cooling with the technology is 8.25 USD/MWht and that AAC could reduce the electricity demand for hydrogen liquefaction by 30%. AAC is an innovative renewable cooling technology that has the potential to complement other renewable energy sources in a sustainable future.

Item Type: Article
Uncontrolled Keywords: renewable cooling; air-conditioning; hydrogen liquefaction; balloons; airships
Research Programs: Energy, Climate, and Environment (ECE)
Energy, Climate, and Environment (ECE) > Integrated Assessment and Climate Change (IACC)
Energy, Climate, and Environment (ECE) > Sustainable Service Systems (S3)
Depositing User: Luke Kirwan
Date Deposited: 08 Jan 2024 08:48
Last Modified: 08 Jan 2024 08:48

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