Your search keyword '"Syrope model"' showing total 3 results

1. On the importance of angle-dependent hydrodynamic coefficients in the equilibrium configuration analysis of synthetic fiber towing ropes.

Author

Li, Gen, Janocha, Marek Jan, Yin, Guang, Ong, Muk Chen, and Li, Wenhua

Subjects

*SYNTHETIC fibers, *LARGE eddy simulation models, *DRAG coefficient, *DRAG force, *DRAG (Aerodynamics), *REYNOLDS number

Abstract

The underwater configuration analysis of a towing rope is crucial for estimating the rope tension and the state of the towed body. In the case where the rope inclination angle significantly increases, the partial hydrodynamic force coefficients of a rope segment should display apparent variations with the local inclination angle. However, constant drag coefficients ignoring the angle-dependent drag effect are widely used in numerical studies. To address the importance of the angle-dependent force coefficients for analyzing the underwater configuration of a towing rope, Large Eddy Simulations are carried out to obtain the drag forces of a cylindrical rope segment with varying inclination angles and Reynolds numbers. To model the rope deformation, a tensile experiment is also conducted to establish the nonlinear tension-strain relationship of the fibre rope. Parametric studies are performed to investigate the difference in the results calculated by both constant and angle-dependent hydrodynamic force coefficients. It was found that the application of constant drag coefficients leads to significant underestimation of the rope tension near the towed body, especially when the rope experiences large inclination angles. Therefore, the present study highlights the importance of using the angle-dependent hydrodynamic coefficients to predict the configuration and tension of towing ropes. • The underwater configuration of a towing rope is analyzed based on the drag coefficient validated by the inclination angle. • Large Eddy Simulations are carried out to obtain the drag coefficients at various inclination angles and Reynolds numbers. • Experiment is performed to establish the tension-elongation relationship of the synthetic fibre rope. • The rope tension predicted by the angle-dependent coefficients may be much larger than the one by constant coefficients. [ABSTRACT FROM AUTHOR]

Published

2024

2. Design and comparative analysis of alternative mooring systems for floating wind turbines in shallow water with emphasis on ultimate limit state design

Author

Xu, Kun, Larsen, Kjell, Shao, Yanlin, Zhang, Min, Gao, Zhen, Moan, Torgeir, Xu, Kun, Larsen, Kjell, Shao, Yanlin, Zhang, Min, Gao, Zhen, and Moan, Torgeir

Abstract

Floating wind turbines represent a cost-efficient energy solution in deep water where bottom-fixed wind turbine becomes excessively expensive. However, mooring design is quite challenging for all shallow water depths including the transition water depth between bottom-fixed and floating wind turbines, in the order of 50–80 m, for which floating concepts might become more cost-effective than bottom-fixed ones. In this paper, mooring system design for floating wind turbine in shallow water are studied considering both catenary and taut mooring systems. Seven mooring concepts designed for a 5 MW semi-submersible floating wind turbine at 50 m water depth are compared with the purpose to identify solutions that are structurally reliable and economically attractive. The concepts are made of different mooring line materials (chain and synthetic fibre rope), mooring components (clump weight and buoy) and anchors (drag embedment anchor and suction anchor). Based on the latest experimental data, the nonlinear tension-dependent stiffness of synthetic fibre rope are described with an improved numerical model. Performance of the seven mooring concepts are compared with respect to mooring line characteristics, motion response amplitude operator, utilization factor considering the ultimate limit state design and cost etc. Six mooring design concepts are finally recommended for future assessment regarding the application of floating wind turbines in shallow water say 50 m and deeper.

Published

2021

3. Design and comparative analysis of alternative mooring systems for floating wind turbines in shallow water with emphasis on ultimate limit state design

Author

Zhen Gao, Torgeir Moan, Yanlin Shao, Kun Xu, Min Zhang, and Kjell Larsen

Subjects

Environmental Engineering, Wind power, Buoy, business.industry, Shallow water, Syrope model, Hybrid mooring design, 020101 civil engineering, Ocean Engineering, Floating wind turbine, 02 engineering and technology, Mooring, 01 natural sciences, Turbine, 010305 fluids & plasmas, 0201 civil engineering, 0103 physical sciences, Catenary, Environmental science, Synthetic fibre rope, Limit state design, business, Marine engineering, Rope

Abstract

Floating wind turbines represent a cost-efficient energy solution in deep water where bottom-fixed wind turbine becomes excessively expensive. However, mooring design is quite challenging for all shallow water depths including the transition water depth between bottom-fixed and floating wind turbines, in the order of 50–80 m, for which floating concepts might become more cost-effective than bottom-fixed ones. In this paper, mooring system design for floating wind turbine in shallow water are studied considering both catenary and taut mooring systems. Seven mooring concepts designed for a 5 MW semi-submersible floating wind turbine at 50 m water depth are compared with the purpose to identify solutions that are structurally reliable and economically attractive. The concepts are made of different mooring line materials (chain and synthetic fibre rope), mooring components (clump weight and buoy) and anchors (drag embedment anchor and suction anchor). Based on the latest experimental data, the nonlinear tension-dependent stiffness of synthetic fibre rope are described with an improved numerical model. Performance of the seven mooring concepts are compared with respect to mooring line characteristics, motion response amplitude operator, utilization factor considering the ultimate limit state design and cost etc. Six mooring design concepts are finally recommended for future assessment regarding the application of floating wind turbines in shallow water say 50 m and deeper.

Published

2021