Abstract
We present a novel methodology for the control of power unit commitment in complex ship energy systems. The usage of this method is demonstrated with a case study, where measured data was used from a cruise ship operating in the Caribbean and the Mediterranean. The ship’s energy system is conceptualized to feature a fuel cell and a battery along standard diesel generating sets for the purpose of reducing local emissions near coasts. The developed method is formulated as a model predictive control (MPC) problem, where a novel 2-stage predictive model is used to predict power demand, and a mixed-integer linear programming (MILP) model is used to solve unit commitment according to the prediction. The performance of the methodology is compared to fully optimal control, which was simulated by optimizing unit commitment for entire measured power demand profiles of trips. As a result, it can be stated that the developed methodology achieves close to optimal unit commitment control for the conceptualized energy system. Furthermore, the predictive model is formulated so that it returns probability estimates of future power demand rather than point estimates. This opens up the possibility for using stochastic or robust optimization methods for unit commitment optimization in future studies.
Highlights
Many industries across the world have pledged to lower atmospheric pollution drastically by2050, including the maritime sector
The emission-related regulations for marine traffic are set by MARPOL Annex VI [2], which limits shipping-related carbon dioxide (CO2 ) emissions via an energy efficiency design index (EEDI) that must be met by newbuilds
This paper presents a methodology for controlling the unit commitment of complex ship energy systems
Summary
Many industries across the world have pledged to lower atmospheric pollution drastically by2050, including the maritime sector. The International Maritime Organization (IMO) has made a preliminary plan on how to reduce shipping-related greenhouse gas (GHG) emissions by 50% by 2050 [1]. The emission-related regulations for marine traffic are set by MARPOL Annex VI [2], which limits shipping-related carbon dioxide (CO2 ) emissions via an energy efficiency design index (EEDI) that must be met by newbuilds. The annex regulates the amount of sulfur in marine fuel to reduce sulfur oxide (SOx ) emissions, especially in emission control areas which are specified by the annex. EEDI is planned as a continuously evolving GHG emission reduction strategy, with new more stringent regulations coming into effect gradually. A unit commitment problem is often formulated as either a stochastic or deterministic optimization problem, where the object to minimize is fuel consumption or emissions or maximize profit. Unit commitment optimization problems are usually characterized by similar sets of constraints, such as power balance constraints, unit ramp-up constraints and maximum unit power rating constraints
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