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System-driven design of flexible nuclear power plant configurations with thermal energy storage
Authors
AA Al Kindi
M Aunedi
+3 more
CN Markides
AM Pantaleo
G Strbac
Publication date
9 June 2023
Publisher
Elsevier
Doi
Abstract
Data availability: Data will be made available on request.A shorter version of this paper has been presented during the 17th Conference on Sustainable Development of Energy, Water and Environment Systems (SDEWES) held in Paphos, Cyprus, 6-10 November 2022.Copyright © 2023 The Author(s).. Nuclear power plants are expected to make an important contribution to the decarbonisation of electricity supply alongside variable renewable generation, especially if their operational flexibility is enhanced by coupling them with thermal energy storage. This paper presents a system modelling approach to identifying configurations of flexible nuclear plants that minimise the investment and operation costs in a decarbonised energy system, effectively proposing a system-driven design of flexible nuclear technology. Case studies presented in the paper explore the impact of system features on plant configuration choices. The results suggest that cost-efficient flexible nuclear configurations should adapt to the system they are located in. In the main low-carbon scenarios and assuming standard-size nuclear power plants (1,610 MWel), the lowest-cost system configuration included around 500 MWel of additional secondary generation capacity coupled to the nuclear power plants, with 4.5 GWhth of thermal storage capacity and a discharging duration of 2.2 h. Net system benefits per unit of flexible nuclear generation for the main scenarios were quantified at £29-33 m/yr for a wind-dominated system and £19-20 m/yr for a solar-dominated system.UK Engineering and Physical Sciences Research Council (EPSRC) [grant number EP/R045518/1] (IDLES Programme)
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Last time updated on 06/11/2023