A wind-to-wake approach for selecting future marine fuels and powertrains
A wind-to-wake approach for selecting future marine fuels and powertrains
Global shipping contributes (2.8%) to greenhouse gas emissions and needs to find future fuels which will allow the International Maritime organisation's 2050 net zero targets to be met. There is much uncertainty as to which fuels should be used between hydrogen, ammonia or methanol as future costs are uncertain. We propose and evaluate a Wind-to-Wake ratio that provides an objective measure based on the amount of renewable energy required to propel a ship. Time domain voyage energy demand profiles are used to simulate the fuel used and emissions for a cruise ship, a research survey vessel, a container ship and a large multi-fuel Liquefied Natural Gas carrier. Alternative ship power systems are investigated using various carbon-based fuels, ammonia and hydrogen either using conventional engines or fuel cells. For all voyage and fuel scenarios the combination of hydrogen and fuel cells uses 30% less renewable energy than ammonia and 26% less than methanol. Hydrogen only emits steam whereas the other fuel scenarios still emit significant amounts of greenhouse gasses.
Future marine fuels, Decarbonisation, Methanol, Ammonia, Hydrogen, Zero emission shipping, Wind-to-Wake
1039-1050
Manias, Panos
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Mckinlay, Charles J.
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Teagle, Damon A.H.
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Hudson, Dominic
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Turnock, Stephen
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6 August 2024
Manias, Panos
e550032b-d811-4f3c-b4da-4f5e542aa8ad
Mckinlay, Charles J.
9f8dc93c-23b1-4399-9ec7-d1233511a61b
Teagle, Damon A.H.
396539c5-acbe-4dfa-bb9b-94af878fe286
Hudson, Dominic
3814e08b-1993-4e78-b5a4-2598c40af8e7
Turnock, Stephen
d6442f5c-d9af-4fdb-8406-7c79a92b26ce
Manias, Panos, Mckinlay, Charles J., Teagle, Damon A.H., Hudson, Dominic and Turnock, Stephen
(2024)
A wind-to-wake approach for selecting future marine fuels and powertrains.
International Journal of Hydrogen Energy, 82, .
(doi:10.1016/j.ijhydene.2024.07.377).
Abstract
Global shipping contributes (2.8%) to greenhouse gas emissions and needs to find future fuels which will allow the International Maritime organisation's 2050 net zero targets to be met. There is much uncertainty as to which fuels should be used between hydrogen, ammonia or methanol as future costs are uncertain. We propose and evaluate a Wind-to-Wake ratio that provides an objective measure based on the amount of renewable energy required to propel a ship. Time domain voyage energy demand profiles are used to simulate the fuel used and emissions for a cruise ship, a research survey vessel, a container ship and a large multi-fuel Liquefied Natural Gas carrier. Alternative ship power systems are investigated using various carbon-based fuels, ammonia and hydrogen either using conventional engines or fuel cells. For all voyage and fuel scenarios the combination of hydrogen and fuel cells uses 30% less renewable energy than ammonia and 26% less than methanol. Hydrogen only emits steam whereas the other fuel scenarios still emit significant amounts of greenhouse gasses.
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More information
Accepted/In Press date: 25 July 2024
e-pub ahead of print date: 6 August 2024
Published date: 6 August 2024
Keywords:
Future marine fuels, Decarbonisation, Methanol, Ammonia, Hydrogen, Zero emission shipping, Wind-to-Wake
Identifiers
Local EPrints ID: 501087
URI: http://eprints.soton.ac.uk/id/eprint/501087
ISSN: 0360-3199
PURE UUID: 2e7cdad5-9295-4555-8869-13d8db1490ca
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Date deposited: 23 May 2025 16:33
Last modified: 25 May 2025 01:55
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Author:
Panos Manias
Author:
Charles J. Mckinlay
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