Reliability prediction for tidal turbines

Marine renewable energy has the potential to form a key part of the renewable electricity generation arsenal that is required for society to prevent catastrophic global warming. Device reliability is one of the great engineering hurdles facing the sector; operating cost effectively in the harsh open...

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Bibliographic Details
Main Author: Ewing, Fraser J.
Other Authors: Shek, Jonathan, Thies, Philipp, Lazakis, Iraklis, Engineering and Physical Sciences Research Council (EPSRC)
Format: Doctoral or Postdoctoral Thesis
Language:English
Published: The University of Edinburgh 2021
Subjects:
turbine assessment
pitch system
Physics of Failure
reliability assessment
tidal turbine design assessment
Arctic
Online Access:https://hdl.handle.net/1842/38256
https://doi.org/10.7488/era/1522
id ftunivedinburgh:oai:era.ed.ac.uk:1842/38256
record_format openpolar
spelling ftunivedinburgh:oai:era.ed.ac.uk:1842/38256 2023-07-30T04:00:07+02:00 Reliability prediction for tidal turbines Ewing, Fraser J. Shek, Jonathan Thies, Philipp Lazakis, Iraklis Engineering and Physical Sciences Research Council (EPSRC) 2021-11-27 application/pdf https://hdl.handle.net/1842/38256 https://doi.org/10.7488/era/1522 en eng The University of Edinburgh Fraser Ewing, P.R. Thies, J.K. Shek and Claudio Bittencourt-Ferreira, Probabilistic failure rate model of a tidal turbine pitch system, Renewable Energy, 2020 Fraser Ewing, P.R. Thies, J.K. Shek and Claudio Bittencourt-Ferreira, A Physics-based prognostics approach for tidal turbines, Proceedings of 2019 IEEE Conference on Prognostics and Health Management Fraser Ewing, P.R. Thies, Iraklis Lazakis and Claudio Bittencourt-Ferreira, Bayesian reliability modelling of a tidal turbine pitch system, Proceedings of 2018 Asian Wave & Tidal Energy Conference Fraser Ewing, P.R. Thies and Benson Waldron, A Bayesian updating framework for simu lating marine energy converter drive train reliability, Proceedings of 2018 Marine Energy Technology Symposium Fraser Ewing, P.R. Thies, J.K. Shek, Benson Waldron and Michael Wilkinson, Reliability prediction for offshore renewable energy: data driven insights, Proceedings of the ASME 2017 36th International Conference on Ocean, Offshore and Arctic Engineering https://hdl.handle.net/1842/38256 http://dx.doi.org/10.7488/era/1522 turbine assessment pitch system Physics of Failure reliability assessment tidal turbine design assessment Thesis or Dissertation Doctoral PhD Doctor of Philosophy 2021 ftunivedinburgh https://doi.org/10.7488/era/1522 2023-07-09T20:33:34Z Marine renewable energy has the potential to form a key part of the renewable electricity generation arsenal that is required for society to prevent catastrophic global warming. Device reliability is one of the great engineering hurdles facing the sector; operating cost effectively in the harsh open ocean is very challenging. The nascent stage of the sector means that accurate reliability assessment of devices is difficult because of a lack of relevant data, uncertainty about loading conditions and a lack of consensus on device designs and architectures. This research develops and applies a suite of reliability prediction methods for use across the tidal turbine development life cycle. A standards based statistical approach is developed for the assessment of the entire turbine; the pitch system is found to have a particularly high failure rate. An empirical approach is developed and applied on a pitch system to allow for the relevant reliability influencing design parameters to be uncovered. A Bayesian framework is developed to enable new information to be incorporated into existing models; this is of particular interest to nascent technologies. Finally a Physics of Failure approach is developed for the pitch system roller bearing unit; measured flow data is used to predict the fatigue life and reliability via a hydrodynamic model. The methods presented along with the results will assist reliability assessment and prediction during tidal turbine design and early operation. Improved reliability assessment at each stage of turbine development can hopefully assist the industry to cross the ’valley of death’ and become commercially viable. Doctoral or Postdoctoral Thesis Arctic Edinburgh Research Archive (ERA - University of Edinburgh)
institution Open Polar
collection Edinburgh Research Archive (ERA - University of Edinburgh)
op_collection_id ftunivedinburgh
language English
topic turbine assessment
pitch system
Physics of Failure
reliability assessment
tidal turbine design assessment
spellingShingle turbine assessment
pitch system
Physics of Failure
reliability assessment
tidal turbine design assessment
Ewing, Fraser J.
Reliability prediction for tidal turbines
topic_facet turbine assessment
pitch system
Physics of Failure
reliability assessment
tidal turbine design assessment
description Marine renewable energy has the potential to form a key part of the renewable electricity generation arsenal that is required for society to prevent catastrophic global warming. Device reliability is one of the great engineering hurdles facing the sector; operating cost effectively in the harsh open ocean is very challenging. The nascent stage of the sector means that accurate reliability assessment of devices is difficult because of a lack of relevant data, uncertainty about loading conditions and a lack of consensus on device designs and architectures. This research develops and applies a suite of reliability prediction methods for use across the tidal turbine development life cycle. A standards based statistical approach is developed for the assessment of the entire turbine; the pitch system is found to have a particularly high failure rate. An empirical approach is developed and applied on a pitch system to allow for the relevant reliability influencing design parameters to be uncovered. A Bayesian framework is developed to enable new information to be incorporated into existing models; this is of particular interest to nascent technologies. Finally a Physics of Failure approach is developed for the pitch system roller bearing unit; measured flow data is used to predict the fatigue life and reliability via a hydrodynamic model. The methods presented along with the results will assist reliability assessment and prediction during tidal turbine design and early operation. Improved reliability assessment at each stage of turbine development can hopefully assist the industry to cross the ’valley of death’ and become commercially viable.
author2 Shek, Jonathan
Thies, Philipp
Lazakis, Iraklis
Engineering and Physical Sciences Research Council (EPSRC)
format Doctoral or Postdoctoral Thesis
author Ewing, Fraser J.
author_facet Ewing, Fraser J.
author_sort Ewing, Fraser J.
title Reliability prediction for tidal turbines
title_short Reliability prediction for tidal turbines
title_full Reliability prediction for tidal turbines
title_fullStr Reliability prediction for tidal turbines
title_full_unstemmed Reliability prediction for tidal turbines
title_sort reliability prediction for tidal turbines
publisher The University of Edinburgh
publishDate 2021
url https://hdl.handle.net/1842/38256
https://doi.org/10.7488/era/1522
genre Arctic
genre_facet Arctic
op_relation Fraser Ewing, P.R. Thies, J.K. Shek and Claudio Bittencourt-Ferreira, Probabilistic failure rate model of a tidal turbine pitch system, Renewable Energy, 2020
Fraser Ewing, P.R. Thies, J.K. Shek and Claudio Bittencourt-Ferreira, A Physics-based prognostics approach for tidal turbines, Proceedings of 2019 IEEE Conference on Prognostics and Health Management
Fraser Ewing, P.R. Thies, Iraklis Lazakis and Claudio Bittencourt-Ferreira, Bayesian reliability modelling of a tidal turbine pitch system, Proceedings of 2018 Asian Wave & Tidal Energy Conference
Fraser Ewing, P.R. Thies and Benson Waldron, A Bayesian updating framework for simu lating marine energy converter drive train reliability, Proceedings of 2018 Marine Energy Technology Symposium
Fraser Ewing, P.R. Thies, J.K. Shek, Benson Waldron and Michael Wilkinson, Reliability prediction for offshore renewable energy: data driven insights, Proceedings of the ASME 2017 36th International Conference on Ocean, Offshore and Arctic Engineering
https://hdl.handle.net/1842/38256
http://dx.doi.org/10.7488/era/1522
op_doi https://doi.org/10.7488/era/1522
_version_ 1772810718434820096

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