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Projects: Projects for Investigator
Reference Number EP/W015102/1
Title CableDyn: Subsea Power Cable Dynamics Under Complex Ocean Environment
Status Started
Energy Categories Renewable Energy Sources(Wind Energy) 80%;
Other Power and Storage Technologies(Electricity transmission and distribution) 20%;
Research Types Basic and strategic applied research 100%
Science and Technology Fields PHYSICAL SCIENCES AND MATHEMATICS (Applied Mathematics) 10%;
ENGINEERING AND TECHNOLOGY (Electrical and Electronic Engineering) 60%;
ENGINEERING AND TECHNOLOGY (Civil Engineering) 10%;
ENVIRONMENTAL SCIENCES (Earth Systems and Environmental Sciences) 20%;
UKERC Cross Cutting Characterisation Not Cross-cutting 100%
Principal Investigator Dr V Venugopal
No email address given
Energy Systems
University of Edinburgh
Award Type Standard
Funding Source EPSRC
Start Date 01 June 2022
End Date 31 May 2025
Duration 36 months
Total Grant Value £1,224,901
Industrial Sectors Energy
Region Scotland
Programme NC : Engineering
 
Investigators Principal Investigator Dr V Venugopal , Energy Systems, University of Edinburgh (99.995%)
  Other Investigator Dr PR Thies , Engineering Computer Science and Maths, University of Exeter (0.001%)
Professor J R Chaplin , Faculty of Engineering and the Environment, University of Southampton (0.001%)
Professor AGL Borthwick , Sch of Engineering and Electronics, University of Edinburgh (0.001%)
Dr L Johanning , Camborne School of Mines, University of Exeter (0.001%)
Dr N Srinil , Sch of Engineering, Newcastle University (0.001%)
  Industrial Collaborator Project Contact , EDF Energy (0.000%)
Project Contact , Sintef, Norway (0.000%)
Project Contact , Offshore Renewable Energy Catapult (0.000%)
Project Contact , Marine Alliance for Science and Technology for Scotland (MASTS) (0.000%)
Project Contact , JDR Cable Systems (Holdings) Ltd (0.000%)
Project Contact , Det Norske Veritas DNV GL UK Limited (0.000%)
Project Contact , Wood Group Kenny Ireland Limited (0.000%)
Web Site
Objectives
Abstract Floating offshore wind turbine (FOWT) deployments are predicted to increase in the future and the outlook is that globally, 6.2 GW of FOWTs will be built in the next 10 years (https://tinyurl.com/camyybxk). Highly dynamic, free hanging power cables transport power generated by these FOWTs to substations and the onshore grid. Safety critical design of such power cables in order for them to operate in the ocean without failure is of utmost importance, given that these cables are highly expensive to install and replace and any down-time of turbine electrical output results in huge revenue loss.In FOWTs, a large length of the power cable, from the base of the floating foundation to the seabed, is directly exposed to dynamic loading caused by ocean waves, currents, and turbulence. Waves move the floating foundation, and currents produce cable oscillations generated by vortex shedding. In the water column a cable experiences enhanced dynamic loads and undergoes complicated motions. When a dynamic cable is installed in deep water, the upper portion of the cable is exposed to high mechanical load and fatigue, and the lower part to substantial hydrostatic pressure. Motion of the floating foundation in surge, sway, and heave causes the power cable to undergo oscillatory motions that in turn promote vortex-induced vibration (VIV) - which is analogous to the vibration experienced by long marine risers used in offshore oil and gas platforms. As a result, large and complex deflections of the cable occur at various locations along its length, altering its mechanical properties and strength, and eventually leading to fatigue-induced failure. The dynamic forces produce cyclical motions of the cable, and a sharp transition in cable stiffness is expected in cases where these motions and loads concentrate toward a rigid connection point. Repetition of the foregoing process and over-bending can also lead to fatigue damage to the cable. To date, hardly any research has been undertaken to investigate the 3-dimensional nature of VIV, dynamic loads, and motion of power cables subject to combined waves, currents, and turbulence. Moreover, no detailed guidance is given in design standards for the offshore wind industry on how to predict, assess, and suppress fatigue failure of dynamic cables under wave-current-turbulence conditions. Power cable failure is much more likely to occur if the design of such cables is based on poor understanding of the hydrodynamic interactions between cables and the ocean environment.This fundamental scientific research aims to investigate the dynamic loading, motion response, impact of vortex induced vibration and its suppression mechanism, and fatigue failure of subsea power cables subjected to combined 3-dimensional waves, currents, and turbulence. This research will be approached by both numerical and physical modelling of power cable's response. Controlled experimental tests on scale models of power cables will be undertaken in Edinburgh University's FloWave wave-current facility where multi-directional waves and currents of various combinations of amplitudes, frequencies, and directions can be generated. Advanced novel phenomenological wake oscillator models, calibrated and validated with FloWave experimental results, will be used to simulate the hydrodynamic behaviour of power cables. The resulting software tools, experimental data, analysis techniques for characterising cable dynamics and VIV, methodologies established for fatigue analysis, and other outcomes of this research will enhance the design of cost-effective power cables. By reducing uncertainty, our research will lead to increased reliability of offshore power cables, of benefit to the power cable manufacturing industry.
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Added to Database 14/07/22