Parametric analysis of a two-body floating-point absorber wave energy converter
In the evolution of floating-point absorber wave energy conversion systems, multiple-body systems are gaining more attention than single-body systems. Meanwhile, the design and operation factors affecting the performance of multiple-body systems are much greater than those of single-body systems. Ho...
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sg-ntu-dr.10356-1715832023-10-31T15:37:59Z Parametric analysis of a two-body floating-point absorber wave energy converter Xu, Qianlong Li, Ye Bennetts, Luke G. Wang, Shangming Zhang, Lijun Xu, Hao Narasimalu, Srikanth Energy Research Institute @ NTU (ERI@N) Science::Physics Wave Energy Converters Absorption Efficiency In the evolution of floating-point absorber wave energy conversion systems, multiple-body systems are gaining more attention than single-body systems. Meanwhile, the design and operation factors affecting the performance of multiple-body systems are much greater than those of single-body systems. However, no systematic study has yet been presented. In this article, a theoretical model is proposed by using a coupled oscillator system consisting of a damper-spring system to represent a two-body system (the floating body and the reacting body). Dimensionless expressions for the motion response and wave power absorption efficiency are derived. With the newly developed model, we prove that an appropriately tuned two-body system can obtain a limiting power absorption width of L / 2 π (L is the incident wavelength) as much as a single-body system. The generic case of a two-body system is presented with numerical simulations as an example. The results show that increasing the damping coefficient can reduce the wave frequency at which the peak of power absorption efficiency occurs. Increasing stiffness can make the wave frequencies for high power absorption efficiency move to a higher frequency region and can also make the spectrum bandwidth for high power absorption efficiency become narrower. Further, we show that the two-body system can absorb more wave energy at low wave frequencies than the single-body system. Published version We acknowledge the National Key R&D Program of China (No. 2019YFB1504402), the National Natural Science Foundation of China (No. 11872248), the Science Foundation of Donghai Laboratory (DH-2022KF0304), and the Australian Research Council (Nos. LP180101109, FT190100404, and DP200102828) for supporting this work. 2023-10-31T05:20:43Z 2023-10-31T05:20:43Z 2023 Journal Article Xu, Q., Li, Y., Bennetts, L. G., Wang, S., Zhang, L., Xu, H. & Narasimalu, S. (2023). Parametric analysis of a two-body floating-point absorber wave energy converter. Physics of Fluids, 35(9), 097115-1-097115-10. https://dx.doi.org/10.1063/5.0161920 1070-6631 https://hdl.handle.net/10356/171583 10.1063/5.0161920 2-s2.0-85171620235 9 35 097115-1 097115-10 en Physics of Fluids © 2023 Author(s). Published under an exclusive license by AIP Publishing. All rights reserved. This article may be downloaded for personal use only. Any other use requires prior permission of the copyright holder. The Version of Record is available online at http://doi.org/10.1063/5.0161920 application/pdf |
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Science::Physics Wave Energy Converters Absorption Efficiency Xu, Qianlong Li, Ye Bennetts, Luke G. Wang, Shangming Zhang, Lijun Xu, Hao Narasimalu, Srikanth Parametric analysis of a two-body floating-point absorber wave energy converter |
| description |
In the evolution of floating-point absorber wave energy conversion systems, multiple-body systems are gaining more attention than single-body systems. Meanwhile, the design and operation factors affecting the performance of multiple-body systems are much greater than those of single-body systems. However, no systematic study has yet been presented. In this article, a theoretical model is proposed by using a coupled oscillator system consisting of a damper-spring system to represent a two-body system (the floating body and the reacting body). Dimensionless expressions for the motion response and wave power absorption efficiency are derived. With the newly developed model, we prove that an appropriately tuned two-body system can obtain a limiting power absorption width of L / 2 π (L is the incident wavelength) as much as a single-body system. The generic case of a two-body system is presented with numerical simulations as an example. The results show that increasing the damping coefficient can reduce the wave frequency at which the peak of power absorption efficiency occurs. Increasing stiffness can make the wave frequencies for high power absorption efficiency move to a higher frequency region and can also make the spectrum bandwidth for high power absorption efficiency become narrower. Further, we show that the two-body system can absorb more wave energy at low wave frequencies than the single-body system. |
| author2 |
Energy Research Institute @ NTU (ERI@N) |
| author_facet |
Energy Research Institute @ NTU (ERI@N) Xu, Qianlong Li, Ye Bennetts, Luke G. Wang, Shangming Zhang, Lijun Xu, Hao Narasimalu, Srikanth |
| format |
Article |
| author |
Xu, Qianlong Li, Ye Bennetts, Luke G. Wang, Shangming Zhang, Lijun Xu, Hao Narasimalu, Srikanth |
| author_sort |
Xu, Qianlong |
| title |
Parametric analysis of a two-body floating-point absorber wave energy converter |
| title_short |
Parametric analysis of a two-body floating-point absorber wave energy converter |
| title_full |
Parametric analysis of a two-body floating-point absorber wave energy converter |
| title_fullStr |
Parametric analysis of a two-body floating-point absorber wave energy converter |
| title_full_unstemmed |
Parametric analysis of a two-body floating-point absorber wave energy converter |
| title_sort |
parametric analysis of a two-body floating-point absorber wave energy converter |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/171583 |
| _version_ |
1781793718353788928 |