S. Savio scite author profile

Availability, reliability and economic sustainability of naval propulsion plants are key elements to cope with because maintenance costs represent a large slice of total operational expenses. Depending on the adopted strategy, impact of maintenance on overall expenses can remarkably vary; for example, letting an asset running up until breakdown can lead to unaffordable costs. As a matter of fact, a desideratum is to progress maintenance technology of ship propulsion systems from breakdown or preventive maintenance up to more effective condition-based maintenance approaches. The central idea in condition-based maintenance is to monitor the propulsion equipment by exploiting heterogeneous sensors, enabling diagnosis and, most of all, prognosis of the propulsion system's components and of their potential future failures. The success of condition-based maintenance clearly hinges on the capability of developing effective predictive models; for this purpose, effective use of machine learning methods is proposed in this article. In particular, authors take into consideration an application of condition-based maintenance to gas turbines used for vessel propulsion, where the performance and advantages of exploiting machine learning methods in modeling the degradation of the propulsion plant over time are tested. Experiments, conducted on data generated from a sophisticated simulator of a gas turbine, mounted on a Frigate characterized by a COmbined Diesel eLectric And Gas propulsion plant type, will allow to show the effectiveness of the proposed machine learning approaches and to benchmark them in a realistic maritime application.

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Data-driven ship digital twin for estimating the speed loss caused by the marine fouling

Coraddu

et al. 2019

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Numerical investigation on ship energy efficiency by Monte Carlo simulation

Coraddu¹,

Figari²,

Savio³

2014

Proceedings of the Institution of Mechanical Engineers, Part M:

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In this article, the authors present a procedure to predict the energy efficiency operational indicator by Monte Carlo simulations, estimating the total ship fuel consumption as a function of displacement and speed considered as random variables. To characterize the probability density function of displacement and speed, a complete series of operating data concerning 2 years of navigation, of a RoPax engaged in a commercial trade in the Mediterranean Sea, were collected and used.

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Influence of the Type and Size of Wind Turbines on Anti-Icing Thermal Power Requirements for Blades

Battisti

Fedrizzi

Savio

et al. 2007

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Unintrusive Monitoring of Induction Motors Bearings via Deep Learning on Stator Currents

Cipollini

Oneto

Coraddu

et al. 2018

Procedia Computer Science

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S. Savio

Machine learning approaches for improving condition-based maintenance of naval propulsion plants

Data-driven ship digital twin for estimating the speed loss caused by the marine fouling

Numerical investigation on ship energy efficiency by Monte Carlo simulation

Influence of the Type and Size of Wind Turbines on Anti-Icing Thermal Power Requirements for Blades

Unintrusive Monitoring of Induction Motors Bearings via Deep Learning on Stator Currents

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