Development of a Predictive Model for Evaluation of the Influence of Various Parameters on the Performance of an Oscillating Water Column Device

Sfravara, Felice; Barberi, Emmanuele; Bongiovanni, Giacomo; Chillemi, Massimiliano; Brusca, Sebastian

doi:10.3390/s24113582

Sensors

2024

DOI: 10.3390/s24113582

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Development of a Predictive Model for Evaluation of the Influence of Various Parameters on the Performance of an Oscillating Water Column Device

Felice Sfravara,

Emmanuele Barberi,

Giacomo Bongiovanni

et al.

Abstract: Oscillating Water Column (OWC) systems harness wave energy using a partially submerged chamber with an underwater opening. The Savonius turbine, a vertical-axis wind turbine, is well-suited for this purpose due to its efficiency at low speeds and self-starting capability, making it an ideal power take-off (PTO) mechanism in OWC systems. This study tested an OWC device with a Savonius turbine in an air duct to evaluate its performance under varying flow directions and loads. An innovative aspect was assessing t… Show more

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OWC Systems Savonius Turbine Reduced Order Model Implementation by Means of Experimental Data

Brusca,

Galvagno,

Mauro

et al. 2024

J. Phys.: Conf. Ser.

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The present paper discusses the implementation of a Reduced Order Model (ROM) for an OWC Power Take-Off Savonius turbine. The turbine’s ROM relies primarily on experimental data. An ad hoc laboratory-scale oscillating flow simulator was constructed to replicate the behaviour of the OWC power take-off turbine under various operating conditions. A laboratory-scale Savonius turbine with a diameter of 0.09 m, an aspect ratio of 1, and an overlap ratio of 1/3 was subjected to testing. Performance evaluations were conducted using the laboratory-scale oscillating flow simulator. In this paper, all tests were conducted at a fixed maximum air velocity of 5 m/s and different air flow oscillation frequencies. A data-driven method was employed to implement the turbine ROM, utilizing data collected during the experimental campaign. To test ROM model air flow oscillation frequency of 1.0 Hz is used.

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OWC Systems Savonius Turbine Reduced Order Model Implementation by Means of Experimental Data

Brusca,

Galvagno,

Mauro

et al. 2024

J. Phys.: Conf. Ser.

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show abstract

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Development of a Predictive Model for Evaluation of the Influence of Various Parameters on the Performance of an Oscillating Water Column Device

Cited by 1 publication

References 49 publications

OWC Systems Savonius Turbine Reduced Order Model Implementation by Means of Experimental Data

OWC Systems Savonius Turbine Reduced Order Model Implementation by Means of Experimental Data

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