Study on force and wave energy conversion efficiency of buoys in low wave energy density seas

[Display omitted] •The buoys of ‘cd’ and ‘hs’ are studied in low energy flow density seas.•The force exerted on buoys is concentric ring distribution.•The conversion efficiency of the ‘cd’ buoy is 1.31% than the ‘hs’ buoy.•Force of ‘cd’ is 194–1455% larger than ‘hs’ under same underwater equivalent...

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Bibliographic Details
Published in:Energy conversion and management 2019-02, Vol.182, p.191-200
Main Authors: Chen, Fei, Duan, Derong, Han, Qing, Yang, Xuefeng, Zhao, Fang
Format: Article
Language:English
Subjects:
Buoys
Converters
Density
Efficiency
Energy
Energy conversion
Energy conversion efficiency
Equivalence
Equivalent area
Flux density
Low wave energy density
Photovoltaic cells
Underwater
Wave energy
Wave energy conversion efficiency
Wave energy converter
Wave power
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Summary:[Display omitted] •The buoys of ‘cd’ and ‘hs’ are studied in low energy flow density seas.•The force exerted on buoys is concentric ring distribution.•The conversion efficiency of the ‘cd’ buoy is 1.31% than the ‘hs’ buoy.•Force of ‘cd’ is 194–1455% larger than ‘hs’ under same underwater equivalent area.•Energy conversion can be obtained using SBWEC in low wave energy density sea areas. The performance of wave energy converters is significantly affected by buoys. This research studied the force and conversion efficiency of buoys in low wave energy density seas and involved the selection of a cylindrical buoy and a hemispherical buoy, which were applied in a sealed-buoy wave energy converter (SBWEC). The underwater equivalent area was utilized as the variable to investigate the force, pitch response amplitude operator (RAO), and conversion efficiency of the buoys in irregular waves. The results show that the common responses occurred both in the cylindrical and hemispherical buoys. The force of the buoys in a resonance state was distributed in a concentric ring shape and gradually decreased from the inner to the outer areas. The force, pitch RAOs, and conversion efficiency increased with a corresponding increase in the underwater equivalent area. Results determined that owing to the difference in the underwater equivalent area and shape, the force of the cylindrical buoy with a diameter 2 m and 4 m was 194–1455% larger than that of the hemispherical buoy with the same diameter. The pitch RAOs of the cylindrical buoy were 0.6–52.59% larger than that of the hemispherical buoy because of the difference in force. In turn, the average conversion efficiency of the cylindrical buoy was 1.31% greater than that of the hemispherical buoy. The novel SBWEC made the wave energy conversion efficiency of the buoys in low wave energy density seas 0.6–1.4% less than that in high wave energy density seas. The utilization of the underwater equivalent area provides a new method for researching the force and conversion efficiency of buoys.
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2018.12.074