Key to the progression of the wave energy extraction sector is reducing
capital costs whilst maintaining or improving energy extraction efficiency.
To achieve this, multiple devices in farm configurations, known as
arrays, are likely to be developed. Mooring and anchorage systems of large
scale arrays have been highlighted as notable contributors to high structural
costs. To minimize the number of anchors required, and thus the cost, one
option is to interconnect devices within the arrays. The implication on array
performance and line tension of this mooring design needs to be understood
to realize the true possibility for cost reduction. Large scale physical tests
were performed in the COAST Laboratory at the University of Plymouth.
An array of five individually moored oscillating water column type wave
energy converters (WEC) were initially tested in operational and extreme
conditions, followed by four interconnected designs of reducing levels of interconnectivity.
Results showed considerable performance implications due
to the interconnecting of devices, with a 75% increase in annual yield for all
levels of connectivity, relative to the individually moored control case. The
performance enhancement was attributed to the interconnecting moorings
altering the system resonant frequency, resulting in a beneficial phase difference
between the water column and the device. Whilst the overall array
performance was not significantly effected by the level of connectivity the
spatial variation in power distribution within the array was. The fatigue line
loading experienced by the interconnecting lines in operational states showed
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beneficial results compared to that experienced by the individually moored
array. However, in extreme sea states, some interconnecting and seabed lines
displayed higher extreme loads compared to the individually moored array
and so would require a higher strength material, incurring possible higher
costs. Due to the improved fatigue characteristics of the interconnected arrays
during operational conditions, these higher performance lines required
would likely have an increased service life that requires complex cost modelling.
This thesis demonstrates a beneficial potential for interconnected
WEC arrays worthy of further investigation.
Date of Award | 2020 |
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Original language | English |
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Awarding Institution | |
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Supervisor | Deborah Greaves (Other Supervisor) |
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- Wave energy
- Physical modelling
- Numerical modelling
- OWC
- Interlinked array
- Moorings
A Physical and Numerical Study of an Interconnected Wave Energy Array
Howey, B. (Author). 2020
Student thesis: PhD