The University of Southampton
×
Filter your search:
University of Southampton Institutional Repository

A robust Logistics-Electric framework for optimal power management of electrified ports under uncertain vessel arrival time

A robust Logistics-Electric framework for optimal power management of electrified ports under uncertain vessel arrival time
A robust Logistics-Electric framework for optimal power management of electrified ports under uncertain vessel arrival time
Maritime transport is responsible for producing a considerable amount of environmental pollution due to the reliance of ports and ships on the carbon-based energy sources. With the increasing trend towards port electrification to reduce carbon emissions, the operation of ports will be increasingly relying on the electricity network. This interconnection creates multiple challenges due to the complexity of power flow in the port network, uncertainty of vessel arrival time and fluctuation of power generation of renewable energy sources. These uncertainties can lead to an overload in electricity networks and delays in cargo-handling activities, resulting in increased vessel handling times and environmental emissions. This paper presents a joint logistics-electric framework for optimal operation and power management of electrified ports, considering multiple uncertainties in the arrival time of vessels, network demand, and renewable power generation. An optimal power flow method is developed for a real-life port, with consideration for multiple port logistic assets such as cargo handling equipment, reefers, and renewable energy sources. The proposed model ensures feasible port operation for all uncertainty realisations defined by robust optimisation, while minimising operational costs. Simulation results demonstrate that the probability of a network constraint violation can be as high as 70% for an electrified major UK port if the uncertainty in the port operation is neglected, presenting an unacceptable risk of disruption to port activities. Furthermore, such uncertainty can cause 150% increase in emissions if the ships use their auxiliary engine instead of using shore power. The numerical study shows that such challenges can be handled by a 0.3% increase in the robustness in face of uncertainty, while the cost increase in the worst case does not exceed 4.7%. This shows the effectiveness of the proposed method enhancing robustness against uncertainty at the minimum cost.
Sarantakos, Ilias
4254bfd4-69e0-445f-a19d-75c0f05a98cc
Nikkhah, Saman
2c625a34-af2e-433f-99ad-aef8e5434350
Peker, Meltem
c94ca4c6-9c42-4fea-acd5-392405540bbd
Bowkett, Annabel
2210b859-8210-4686-bae7-42ddc491a4c9
Sayfutdinov, Timur
c8273fcc-6e3c-4824-9e9a-7adc785f9a30
Alahyari, Arman
48ed327a-9a35-402e-8170-a3f491005ae7
Patsios, Charalampos
8eb5780c-fa8e-4858-b929-b60b20b82634
Mangan, John
a10c51ec-17d4-49f9-9719-945c5f611791
Allahham, Adib
59f9c935-6dc0-43d2-accf-846a2e3c1ca1
Bougioukou, Eleni
ac7a5fbd-4003-45cd-aaeb-5436bde33a1c
Murphy, Alan
8e021dad-0c60-446b-a14e-cddd09d44626
Pazouki, Kayvan
1e69a646-83da-49ce-af3a-c40808c83ffe
Sarantakos, Ilias
4254bfd4-69e0-445f-a19d-75c0f05a98cc
Nikkhah, Saman
2c625a34-af2e-433f-99ad-aef8e5434350
Peker, Meltem
c94ca4c6-9c42-4fea-acd5-392405540bbd
Bowkett, Annabel
2210b859-8210-4686-bae7-42ddc491a4c9
Sayfutdinov, Timur
c8273fcc-6e3c-4824-9e9a-7adc785f9a30
Alahyari, Arman
48ed327a-9a35-402e-8170-a3f491005ae7
Patsios, Charalampos
8eb5780c-fa8e-4858-b929-b60b20b82634
Mangan, John
a10c51ec-17d4-49f9-9719-945c5f611791
Allahham, Adib
59f9c935-6dc0-43d2-accf-846a2e3c1ca1
Bougioukou, Eleni
ac7a5fbd-4003-45cd-aaeb-5436bde33a1c
Murphy, Alan
8e021dad-0c60-446b-a14e-cddd09d44626
Pazouki, Kayvan
1e69a646-83da-49ce-af3a-c40808c83ffe

Sarantakos, Ilias, Nikkhah, Saman, Peker, Meltem, Bowkett, Annabel, Sayfutdinov, Timur, Alahyari, Arman, Patsios, Charalampos, Mangan, John, Allahham, Adib, Bougioukou, Eleni, Murphy, Alan and Pazouki, Kayvan (2024) A robust Logistics-Electric framework for optimal power management of electrified ports under uncertain vessel arrival time. Cleaner Logistics and Supply Chain, 10, [100144]. (doi:10.1016/j.clscn.2024.100144).

Record type: Article

Abstract

Maritime transport is responsible for producing a considerable amount of environmental pollution due to the reliance of ports and ships on the carbon-based energy sources. With the increasing trend towards port electrification to reduce carbon emissions, the operation of ports will be increasingly relying on the electricity network. This interconnection creates multiple challenges due to the complexity of power flow in the port network, uncertainty of vessel arrival time and fluctuation of power generation of renewable energy sources. These uncertainties can lead to an overload in electricity networks and delays in cargo-handling activities, resulting in increased vessel handling times and environmental emissions. This paper presents a joint logistics-electric framework for optimal operation and power management of electrified ports, considering multiple uncertainties in the arrival time of vessels, network demand, and renewable power generation. An optimal power flow method is developed for a real-life port, with consideration for multiple port logistic assets such as cargo handling equipment, reefers, and renewable energy sources. The proposed model ensures feasible port operation for all uncertainty realisations defined by robust optimisation, while minimising operational costs. Simulation results demonstrate that the probability of a network constraint violation can be as high as 70% for an electrified major UK port if the uncertainty in the port operation is neglected, presenting an unacceptable risk of disruption to port activities. Furthermore, such uncertainty can cause 150% increase in emissions if the ships use their auxiliary engine instead of using shore power. The numerical study shows that such challenges can be handled by a 0.3% increase in the robustness in face of uncertainty, while the cost increase in the worst case does not exceed 4.7%. This shows the effectiveness of the proposed method enhancing robustness against uncertainty at the minimum cost.

Text
1-s2.0-S2772390924000064-main - Version of Record
Available under License Creative Commons Attribution Non-commercial No Derivatives.
Download (1MB)

More information

Accepted/In Press date: 15 January 2024
e-pub ahead of print date: 28 January 2024
Published date: 28 January 2024

Identifiers

Local EPrints ID: 498744
URI: http://eprints.soton.ac.uk/id/eprint/498744
DOI: doi:10.1016/j.clscn.2024.100144
PURE UUID: 07752cce-5714-4487-8c58-21afec301d9c

Catalogue record

Date deposited: 26 Feb 2025 17:37
Last modified: 21 Aug 2025 03:41

Export record

Altmetrics

Contributors

Author: Ilias Sarantakos
Author: Saman Nikkhah
Author: Meltem Peker
Author: Annabel Bowkett
Author: Timur Sayfutdinov
Author: Arman Alahyari
Author: Charalampos Patsios
Author: John Mangan
Author: Adib Allahham
Author: Eleni Bougioukou
Author: Alan Murphy
Author: Kayvan Pazouki

Download statistics

Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.

View more statistics

Library staff additional information
Atom RSS 1.0 RSS 2.0

Contact ePrints Soton: eprints@soton.ac.uk

ePrints Soton supports OAI 2.0 with a base URL of http://eprints.soton.ac.uk/cgi/oai2

This repository has been built using EPrints software, developed at the University of Southampton, but available to everyone to use.

We use cookies to ensure that we give you the best experience on our website. If you continue without changing your settings, we will assume that you are happy to receive cookies on the University of Southampton website.

×