TY - JOUR
T1 - Fatigue-life prediction methods of a dynamic power cable for a floating testing platform - a numerical approach
AU - Benites-Munoz, Daniela
AU - Ricci, Pierpaolo
AU - Touzon, Imanol
AU - Salcedo, Fernando
AU - Raymond, Rupert
AU - Nunes, Diogo
N1 - Publisher Copyright:
© 2023 European Wave and Tidal Energy Conference.
PY - 2023
Y1 - 2023
N2 - Power cables are often used to connect marine systems to subsea electric grids. These cables are commonly exposed to the cyclic loads resulting from the waves, current and the floater’s motions. Hence, the fatigue life plays a crucial role in the design stage of the behaviour and integrity of power cables. This paper addresses the fatigue-based design of a dynamic power cable deployed to connect a floating testing platform, HarshLab 2.0. Different fatigue-life prediction methods are examined, considering the damage in the steel armour and the conductor cores of the cable. The study is undertaken by estimating each cable component’s long-term cyclic loading and comparing it with its resistance to fatigue damage. In this case, the damage for each variable was derived from σ−N and ϵ−N curves, depending on the selected approach. The design iterative process led to the definition of a Lazy Wave design with a high-level optimisation of some components, e.g., the ballast and buoyancy modules and the bend stiffener. Generally, the behaviour across the cable length is similar between the different fatigue-life approaches, with the most significant expected fatigue damage found in localised hot spots near the bend stiffener and the belly (sag-bend region) of the cable. It is found that, despite a significant difference across the magnitude of fatigue life estimated in sensitive areas, the proposed layout complies with the fatigue life design criteria.
AB - Power cables are often used to connect marine systems to subsea electric grids. These cables are commonly exposed to the cyclic loads resulting from the waves, current and the floater’s motions. Hence, the fatigue life plays a crucial role in the design stage of the behaviour and integrity of power cables. This paper addresses the fatigue-based design of a dynamic power cable deployed to connect a floating testing platform, HarshLab 2.0. Different fatigue-life prediction methods are examined, considering the damage in the steel armour and the conductor cores of the cable. The study is undertaken by estimating each cable component’s long-term cyclic loading and comparing it with its resistance to fatigue damage. In this case, the damage for each variable was derived from σ−N and ϵ−N curves, depending on the selected approach. The design iterative process led to the definition of a Lazy Wave design with a high-level optimisation of some components, e.g., the ballast and buoyancy modules and the bend stiffener. Generally, the behaviour across the cable length is similar between the different fatigue-life approaches, with the most significant expected fatigue damage found in localised hot spots near the bend stiffener and the belly (sag-bend region) of the cable. It is found that, despite a significant difference across the magnitude of fatigue life estimated in sensitive areas, the proposed layout complies with the fatigue life design criteria.
KW - Dynamic power cable
KW - Fatigue-life prediction
KW - Numerical modelling
KW - OrcaFlex
UR - http://www.scopus.com/inward/record.url?scp=85208437678&partnerID=8YFLogxK
U2 - 10.36688/ewtec-2023-410
DO - 10.36688/ewtec-2023-410
M3 - Conference article
AN - SCOPUS:85208437678
SN - 2706-6932
JO - Proceedings of the European Wave and Tidal Energy Conference
JF - Proceedings of the European Wave and Tidal Energy Conference
T2 - 15th European Wave and Tidal Energy Conference, EWTEC 2023
Y2 - 3 September 2023 through 7 September 2023
ER -