Integrated investment, retrofit and abandonment energy system planning with multi-timescale uncertainty using stabilised adaptive Benders decomposition
Integrated investment, retrofit and abandonment energy system planning with multi-timescale uncertainty using stabilised adaptive Benders decomposition
We propose the REORIENT (REnewable resOuRce Investment for the ENergy Transition) model for energy systems planning with the following novelties: (1) integrating capacity expansion, retrofit and abandonment planning, and (2) using multi-horizon stochastic mixed-integer linear programming with multi-timescale uncertainty. We apply the model to the European energy system considering: (a) investment in new hydrogen infrastructures, (b) capacity expansion of the European power system, (c) retrofitting oil and gas infrastructures in the North Sea region for hydrogen production and distribution, and abandoning existing infrastructures, and (d) long-term uncertainty in oil and gas prices and short-term uncertainty in time series parameters. We utilise the structure of multi-horizon stochastic programming and propose a stabilised adaptive Benders decomposition to solve the model efficiently. We first conduct a sensitivity analysis on retrofitting costs of oil and gas infrastructures. We then compare the REORIENT model with a conventional investment planning model regarding costs and investment decisions. Finally, the computational performance of the algorithm is presented. The results show that: (1) when the retrofitting cost is below 20% of the cost of building new ones, retrofitting is economical for most of the existing pipelines, (2) platform clusters keep producing oil due to the massive profit, and the clusters are abandoned in the last investment stage, (3) compared with a traditional investment planning model, the REORIENT model yields 24% lower investment cost in the North Sea region, and (4) the enhanced Benders algorithm is up to 6.8 times faster than the level method stabilised adaptive Benders.
Large-scale mixed-integer linear programming, Multi-horizon stochastic programming, OR in energy, Retrofit of energy systems, Stochastic programming
261-280
Zhang, Hongyu
ac1b2192-da88-4074-bd67-696146f2d6c0
Grossmann, Ignacio E.
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McKinnon, Ken
66558b38-692b-4de9-9eac-df24d41c4f6d
Knudsen, Brage Rugstad
8d23b422-a68a-488d-8880-7643cb4babe8
Nava, Rodrigo Garcia
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Tomasgard, Asgeir
623a1e56-f338-4820-851d-97f55fe92fc0
1 September 2025
Zhang, Hongyu
ac1b2192-da88-4074-bd67-696146f2d6c0
Grossmann, Ignacio E.
2bc893c8-fecc-4831-848d-2b5bed5f9720
McKinnon, Ken
66558b38-692b-4de9-9eac-df24d41c4f6d
Knudsen, Brage Rugstad
8d23b422-a68a-488d-8880-7643cb4babe8
Nava, Rodrigo Garcia
bc89925d-9e9d-415d-9eda-1ad03ce58be0
Tomasgard, Asgeir
623a1e56-f338-4820-851d-97f55fe92fc0
Zhang, Hongyu, Grossmann, Ignacio E., McKinnon, Ken, Knudsen, Brage Rugstad, Nava, Rodrigo Garcia and Tomasgard, Asgeir
(2025)
Integrated investment, retrofit and abandonment energy system planning with multi-timescale uncertainty using stabilised adaptive Benders decomposition.
European Journal of Operational Research, 325 (2), .
(doi:10.1016/j.ejor.2025.04.005).
Abstract
We propose the REORIENT (REnewable resOuRce Investment for the ENergy Transition) model for energy systems planning with the following novelties: (1) integrating capacity expansion, retrofit and abandonment planning, and (2) using multi-horizon stochastic mixed-integer linear programming with multi-timescale uncertainty. We apply the model to the European energy system considering: (a) investment in new hydrogen infrastructures, (b) capacity expansion of the European power system, (c) retrofitting oil and gas infrastructures in the North Sea region for hydrogen production and distribution, and abandoning existing infrastructures, and (d) long-term uncertainty in oil and gas prices and short-term uncertainty in time series parameters. We utilise the structure of multi-horizon stochastic programming and propose a stabilised adaptive Benders decomposition to solve the model efficiently. We first conduct a sensitivity analysis on retrofitting costs of oil and gas infrastructures. We then compare the REORIENT model with a conventional investment planning model regarding costs and investment decisions. Finally, the computational performance of the algorithm is presented. The results show that: (1) when the retrofitting cost is below 20% of the cost of building new ones, retrofitting is economical for most of the existing pipelines, (2) platform clusters keep producing oil due to the massive profit, and the clusters are abandoned in the last investment stage, (3) compared with a traditional investment planning model, the REORIENT model yields 24% lower investment cost in the North Sea region, and (4) the enhanced Benders algorithm is up to 6.8 times faster than the level method stabilised adaptive Benders.
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2025_Zhang_REORIENT
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Accepted/In Press date: 3 April 2025
e-pub ahead of print date: 11 April 2025
Published date: 1 September 2025
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© 2025 The Authors
Keywords:
Large-scale mixed-integer linear programming, Multi-horizon stochastic programming, OR in energy, Retrofit of energy systems, Stochastic programming
Identifiers
Local EPrints ID: 501658
URI: http://eprints.soton.ac.uk/id/eprint/501658
ISSN: 0377-2217
PURE UUID: d0f1bb9f-aba6-4f8b-8441-aa93425d13d6
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Date deposited: 04 Jun 2025 17:17
Last modified: 22 Aug 2025 02:46
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Contributors
Author:
Hongyu Zhang
Author:
Ignacio E. Grossmann
Author:
Ken McKinnon
Author:
Brage Rugstad Knudsen
Author:
Rodrigo Garcia Nava
Author:
Asgeir Tomasgard
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