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Multi-objective evolutionary optimisation of the geometry of a class of controlled wave energy converter.

Research output: Contribution in Book/Report/Proceedings - With ISBN/ISSNConference contribution/Paperpeer-review

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Multi-objective evolutionary optimisation of the geometry of a class of controlled wave energy converter. / Gunn, Kester; Lingwood, Chris; Taylor, C. James.
UKACC International Conference Control 2010. ed. / K.J. Burnham; V.E. Ersanilli. 2010. p. 349-354.

Research output: Contribution in Book/Report/Proceedings - With ISBN/ISSNConference contribution/Paperpeer-review

Harvard

Gunn, K, Lingwood, C & Taylor, CJ 2010, Multi-objective evolutionary optimisation of the geometry of a class of controlled wave energy converter. in KJ Burnham & VE Ersanilli (eds), UKACC International Conference Control 2010. pp. 349-354.

APA

Gunn, K., Lingwood, C., & Taylor, C. J. (2010). Multi-objective evolutionary optimisation of the geometry of a class of controlled wave energy converter. In K. J. Burnham, & V. E. Ersanilli (Eds.), UKACC International Conference Control 2010 (pp. 349-354)

Vancouver

Gunn K, Lingwood C, Taylor CJ. Multi-objective evolutionary optimisation of the geometry of a class of controlled wave energy converter. In Burnham KJ, Ersanilli VE, editors, UKACC International Conference Control 2010. 2010. p. 349-354

Author

Gunn, Kester ; Lingwood, Chris ; Taylor, C. James. / Multi-objective evolutionary optimisation of the geometry of a class of controlled wave energy converter. UKACC International Conference Control 2010. editor / K.J. Burnham ; V.E. Ersanilli. 2010. pp. 349-354

Bibtex

@inproceedings{08cb49a946a24c73a077d5663d4dfdc7,
title = "Multi-objective evolutionary optimisation of the geometry of a class of controlled wave energy converter.",
abstract = "Concerns over climate change and energy security help motivate research into wave energy converters (WEC). Two WEC topologies have shown particular promise and many proposed devices rely on these forms, namely the heaving buoy and the bottom hinged surging flap. It can be shown that to achieve resonance a heaving point absorber requires a diameter that is much larger than practical. By contrast, bottom hinged flaps are generally smaller, hence many hinged flap devices are non resonant. This paper proposes a hybrid of these two topologies, in the form of an off-set hinged flap. The exact form is determined using a novel Multi-Objective Evolutionary Algorithm. The latter has been developed by the authors to address difficult discontinuous optimisation problems like this. The device volume is minimised, whilst simultaneously maximising power capture under both active and passive control.",
keywords = "Multi-objective evolutionary optimisation, wave energy converter",
author = "Kester Gunn and Chris Lingwood and Taylor, {C. James}",
note = "Coventry University Paper 71",
year = "2010",
month = sep,
language = "English",
isbn = "978-184600-0386",
pages = "349--354",
editor = "K.J. Burnham and V.E. Ersanilli",
booktitle = "UKACC International Conference Control 2010",

}

RIS

TY - GEN

T1 - Multi-objective evolutionary optimisation of the geometry of a class of controlled wave energy converter.

AU - Gunn, Kester

AU - Lingwood, Chris

AU - Taylor, C. James

N1 - Coventry University Paper 71

PY - 2010/9

Y1 - 2010/9

N2 - Concerns over climate change and energy security help motivate research into wave energy converters (WEC). Two WEC topologies have shown particular promise and many proposed devices rely on these forms, namely the heaving buoy and the bottom hinged surging flap. It can be shown that to achieve resonance a heaving point absorber requires a diameter that is much larger than practical. By contrast, bottom hinged flaps are generally smaller, hence many hinged flap devices are non resonant. This paper proposes a hybrid of these two topologies, in the form of an off-set hinged flap. The exact form is determined using a novel Multi-Objective Evolutionary Algorithm. The latter has been developed by the authors to address difficult discontinuous optimisation problems like this. The device volume is minimised, whilst simultaneously maximising power capture under both active and passive control.

AB - Concerns over climate change and energy security help motivate research into wave energy converters (WEC). Two WEC topologies have shown particular promise and many proposed devices rely on these forms, namely the heaving buoy and the bottom hinged surging flap. It can be shown that to achieve resonance a heaving point absorber requires a diameter that is much larger than practical. By contrast, bottom hinged flaps are generally smaller, hence many hinged flap devices are non resonant. This paper proposes a hybrid of these two topologies, in the form of an off-set hinged flap. The exact form is determined using a novel Multi-Objective Evolutionary Algorithm. The latter has been developed by the authors to address difficult discontinuous optimisation problems like this. The device volume is minimised, whilst simultaneously maximising power capture under both active and passive control.

KW - Multi-objective evolutionary optimisation

KW - wave energy converter

M3 - Conference contribution/Paper

SN - 978-184600-0386

SP - 349

EP - 354

BT - UKACC International Conference Control 2010

A2 - Burnham, K.J.

A2 - Ersanilli, V.E.

ER -