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Reference optimisation of uncertain offshore hybrid power systems with multi-stage nonlinear model predictive control

Abstract

This paper presents a modified multi-stage economic nonlinear model predictive controller (M-ENMPC) for reference optimisation of isolated, uncertain offshore hybrid power systems (OHPSs). These systems require control strategies that can handle significant stochastic disturbances in exogenous power demand and wind, given uncertain forecasts of the disturbances. An M-ENMPC modified with a certainty horizon is formulated to hande uncertain forecasts of these disturbances for reference optimisation of OHPSs. The certainty horizon models the increase in uncertainty of forecasts with time to decrease the cost in the M-ENMPC. Monte Carlo simulations with different realisations of the considered disturbances show that explicitly considering scenarios of the disturbances with the M-ENMPC can decrease greenhouse gas (GHG) emissions by operating the gas turbines in the hybrid power system more efficiently while achieving an acceptable satisfaction of the exogenous power demand. Furthermore, the Monte Carlo simulations show that using the modified M-ENMPC decreases the average computational time by 17% compared with the conventional M-ENMPC from the literature.
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Category

Academic chapter/article/Conference paper

Client

  • Research Council of Norway (RCN) / 296207

Language

English

Author(s)

Affiliation

  • Norwegian University of Science and Technology
  • SINTEF Energy Research / Gassteknologi

Year

2023

Publisher

IEEE (Institute of Electrical and Electronics Engineers)

Book

2023 American Control Conference (ACC 2023)

Issue

2023

ISBN

979-8-3503-2806-6

Page(s)

1251 - 1257

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