Abstract
In recent decades, the design of ship propulsion systems has been focusing on energy efficiency and low pollutant emissions. In this framework, diesel–electric propulsion has become a standard for many ship types and has proven its worth for flexible propulsion design and management. This paper presents an approach to the optimal design of diesel–electric propulsion systems, minimising the fuel consumption while meeting the power and speed requirements. A genetic algorithm performs the optimisation, used to determine the number and type of engines installed on-board and the engines’ design speed and power, selecting within a dataset of four-stroke diesel engines. The same algorithm is then adapted and applied to determine the optimal load sharing strategy in off-design conditions, taking advantage of the high flexibility of the diesel–electric propulsion plants. In order to apply the algorithm, the propulsion layout design is formulated as an optimisation problem, translating the system requirements into a cost function and a set of linear and non-linear constraints. Eventually, the method is applied to a case study vessel: first, the optimal diesel–electric propulsion plants are determined, then the optimal off-design load sharing and working conditions are computed. AC and DC network solutions are compared and critically discussed in both design and off-design conditions.
Highlights
Traditional ship propulsion systems mainly rely on thermal engines, such as diesel engines [1,2] or gas turbines [3], mechanically connected to either fixed or controllable pitch propellers, most of the time through a reduction gear
This paper aims to present a method for the optimal design of diesel–electric ship propulsion systems, based on parametric modelling of the system layout and performance, which is optimised using a genetic algorithm [27,28]
In the variable diesel generators (D/G) speed case, this would result in a significant amount of computation that might be handled by, for instance, discretising each engine’s load diagram and using a brute force approach to evaluate all the possible working point combinations
Summary
Traditional ship propulsion systems mainly rely on thermal engines, such as diesel engines [1,2] or gas turbines [3], mechanically connected to either fixed or controllable pitch propellers, most of the time through a reduction gear. This propulsion plant layout has several clear advantages, such as being based on simple and well-consolidated technologies [4], ensuring reliability and safety. Combined propulsion plants [7,8,9,10] coupled with controllable pitch propellers can match the operating requirements of ships that require more flexible profiles, for instance, ferries that steam at a different speed in winter or summer season or for navy vessels
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