Hydrodynamic Performance of Air-Filled Wave Attenuator for
Wave Control: Experimental Study

doi:10.1007/s12204-022-2444-3

摘要/Abstract

Abstract: Numerous types of floating breakwaters have been proposed, tested and commercialized in the past decades. The majority of these breakwaters are made of solid bodies; hence, they are relatively bulky and are not readily to be rapidly installed at the targeted sites when immediate wave protection of the coastal and offshore facilities is needed. Furthermore, the application of these hard floating structures at the recreational beaches is rather unlikely due to potential deadly marine traffic collision. To overcome these problems, a flexible air-filled wave attenuator (AFWA) has been developed in the present study. This floating breakwater is made of flexible waterproof membrane materials. The main body consists of a rectangular air-filled prism and is ballasted by sandbags located around the floating module. The objective of this study is to evaluate the wave transmission, wave reflection, energy dissipation, motion responses and mooring forces of the AFWA under the random wave actions using physical modelling. The test model located in a 20 m long wave flume was subjected to a range of wave heights and periods. The wave profiles in the vicinity of the test model were measured using wave probes for determination of wave transmission, reflection and energy loss coefficients. The motion responses in terms of heave, surge and pitch, and wave forces acting on the mooring lines were measured using a motion tracking system and load cells, respectively. The experimental results reveal that the AFWA is effective in attenuating up to 95% in the incoming wave height and has low-wave-reflection properties, which is commendable for floating breakwaters.

Key words: floating breakwater, air-filled wave attenuator (AFWA), hydrodynamic performance, wave attenua tion, motion responses, mooring forces

中图分类号:

O 35

. [J]. J Shanghai Jiaotong Univ Sci, 2022, 27(3): 316-325.

PEREIRA Eric Joseph1 (佩雷拉·埃里克·约瑟夫), TEH Hee-Min1,2∗ (郑希铭), MA Zhe3 (马哲). Hydrodynamic Performance of Air-Filled Wave Attenuator for Wave Control: Experimental Study[J]. J Shanghai Jiaotong Univ Sci, 2022, 27(3): 316-325.

参考文献 23

[1]	FOWLER J, RESIO D, BRIGGS M, et al. Potential uses for the rapidly installed breakwater system [C]//25th International Conference on Coastal Engineering. Orlando, Florida: ASCE, 1996: 1631-1639.
[2]	TEH H M, AZIZAN M S M, KURIAN V J, et al. Use of a floating breakwater system as an environmentally friendly method of coastal shelter [J]. WIT Transactions on the Built Environment, 2015, 148: 309-318.
[3]	MCCARTNEY B L. Floating breakwater design [J]. Journal of Waterway, Port, Coastal, and Ocean Engineering, 1985, 111(2): 304-318.
[4]	TEH H M. Hydraulic performance of free surface breakwaters: A review [J]. Journal of Sains Malaysian, 2013, 42(9): 1301-1310.
[5]	DAI J, W ANG C M, UTSUNOMIYA T, et al. Review of recent research and developments on floating breakwaters [J]. Ocean Engineering, 2018, 158: 132-151.
[6]	HALES L Z. Floating breakwaters: State-of-the-art literature review [R]. Fort Belvoir, V A: NTIS, 1981.
[7]	KOUTANDOS E V, PRINOS P E. Hydrodynamic characteristics of semi-immersed breakwater with an attached porous plate [J]. Ocean Engineering, 2011, 38(1): 34-48.
[8]	JI C Y, CHEN X, CUI J, et al. Experimental study on configuration optimization of floating breakwaters [J]. Ocean Engineering, 2016, 117: 302-310.
[9]	BHAT S S. Performance of twin-pontoon floating breakwaters [D]. Vancouver: University of British Columbia, 1998.
[10]	DIAMANTOULAKI I, LOUKOGEORGAKI E, ANGELIDES D C. 3D analysis of free and moored twinpontoon floating breakwaters [C]//17th International Offshore and Polar Engineering Conference. L i s b o n : ISOPE, 2007: 2515-2522.
[11]	CHEN Z J, W ANG Y X, DONG H Y, et al. Timedomain hydrodynamic analysis of pontoon-plate floating breakwater [J]. Water Science and Engineering, 2012, 5(3): 291-303.
[12]	NEELAMANI S, LJUBIC J. Experimental study on the hydrodynamic performance of floating pontoon type breakwater with skirt walls [J]. Journal of Offshore Mechanics and Arctic Engineering, 2018, 140(2): 021303.
[13]	RAO P M, MADHA V BABU M G. Performance of floating breakwater models under regular waves [C]//16th International Offshore and Polar Engineering Conference. San Francisco, California: ISOPE, 2006: 849-854.
[14]	YANG Z W, XIE M X, GAO Z L, et al. Experimental investigation on hydrodynamic effectiveness of a water ballast type floating breakwater [J]. Ocean Engineering, 2018, 167: 77-94.
[15]	SA W ARAGI T. Chapter 4 Structures for wave control [M]//Developments in geotechnical engineering. Amsterdam: Elsevier, 1995: 211-270.
[16]	JI C Y, CHENG Y, YANG K, et al. Numerical and experimental investigation of hydrodynamic performance of a cylindrical dual pontoon-net floating breakwater [J]. Coastal Engineering, 2017, 129: 1-16.
[17]	KEE S T, CHO W C, SHIN M S, et al. Rapidly installed membrane breakwater in the oblique seas [C]//14th International Offshore and Polar Engineering Conference. Toulon: ISOPE, 2004: 648-654.
[18]	PEREIRA E J, TEH H M, CHAN W L, et al. Performance efficiency of a membrane-type floating breakwater for protection of coastal and offshore facilities [J]. IOP Conference Series: Earth and Environmental Science, 2020, 498(1): 012058.
[19]	BRIGGS M J. Performance characteristics of a rapidly installed breakwater system [R]. U. S. Army Engineer Research and Development Center (ERDC), Coastal and Hydaulics Laboratory (CHL), 2001.
[20]	SCHMITT P, ELS ??ER B. The application of Froude scaling to model tests of oscillating wave surge converters [J]. Ocean Engineering, 2017, 141: 108-115.
[21]	MANSARD E, FUNKE E. The measurement of incident and reflected spectra using a least squares method [C]//17th International Conference on Coastal Engineering. Sydney: ASCE, 1980: 154-172.
[22]	TEH H M, MOHAMMED N I. Wave interactions with a floating breakwater [C]//2012 IEEE Colloquium on Humanities, Science and Engineering. Kota Kinabalu: IEEE, 2012: 84-87.
[23]	HUANG Z H, HE F, ZHANG W B. A floating box-type breakwater with slotted barriers [J]. Journal of Hydraulic Research, 2014, 52(5): 720-727.

Hydrodynamic Performance of Air-Filled Wave Attenuator for Wave Control: Experimental Study

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献 23

相关文章 12

编辑推荐

Metrics

本文评价

[1]	JIANG Chenqi (江晨琦), GONG Zhaoxin (宫兆新) . Effect of Deflectors on the Flow Characteristics of a Square Pipe with a 90° Bend[J]. J Shanghai Jiaotong Univ Sci, 2021, 26(2): 163-169.
[2]	SUN Na (孙娜), WANG Lipo (王利坡), LI Yuanbo (李渊博), LI Lin (李琳), QI Shuaipeng (齐帅鹏), SHEN Yongxing (沈泳星). Scaling Relation of the Scalar Diffusion in a Rotating Mixer[J]. J Shanghai Jiaotong Univ Sci, 2021, 26(2): 170-175.
[3]	ZHAO Yong (赵勇), MENG Yang (孟杨), YU Pengyao (于鹏垚), WANG Tianlin (王天霖), SU Shaojua. Prediction of Fluid Force Exerted on Bluff Body by Neural Network Method[J]. Journal of Shanghai Jiao Tong University (Science), 2020, 25(2): 186-192.
[4]	DUAN Ningyuan (段宁远), CHEN Ke* (陈科), WANG Hongwei (王宏伟), YOU Yunxiang (尤云祥). Characteristics of the Internal Waves Generated by a Towed Model with Rotating Propeller Under a Strong Halocline[J]. Journal of Shanghai Jiao Tong University (Science), 2019, 24(2): 176-183.
[5]	CHEN Xin (陈鑫), LI Ming *(李铭). Delayed Detached Eddy Simulation of Subcritical Flow past Generic Side Mirror[J]. Journal of Shanghai Jiao Tong University (Science), 2019, 24(1): 107-112.
[6]	AN Xinyu *(安新宇), SONG Baowei (宋保维), TIAN Wenlong (田文龙), MA Congcong (马聪聪). Numerical Research of Flow past a Circular Cylinder with Splitter Plate at a Subcritical Reynolds Number Region[J]. Journal of Shanghai Jiao Tong University (Science), 2019, 24(1): 113-121.
[7]	CHEN Ke* (陈科), ZHAO Kai (赵恺), YOU Yunxiang (尤云祥). Numerical Study on Flow Structure of a Shallow Laminar Round Jet[J]. 上海交通大学学报（英文版）, 2017, 22(3): 257-264.
[8]	HUANG Qiaogao (黄桥高), PAN Guang*(潘光). Numerical Simulation of Viscous Flow over a Grooved Surface by the Lattice Boltzmann Method[J]. 上海交通大学学报（英文版）, 2016, 21(2): 143-150.
[9]	潘展程, 鲁传敬, 陈瑛. [J]. Journal of Shanghai Jiao Tong University(Science), 2015, 20(6): 713-720.
[10]	WANG Ying-guang (王迎光). Free-Surface Wave Interaction with a Very Large Floating Structure[J]. 上海交通大学学报（英文版）, 2014, 19(6): 728-735.
[11]	YU Qiana (余谦), ZHANG Huai-xina,b* (张怀新), SUN Xue-yaoa (孙学尧). Research on Numerical Wave Tank Based on the Improved Moving-Particle Semi-Implicit Method with Large Eddy Simulation[J]. 上海交通大学学报（英文版）, 2014, 19(2): 226-232.
[12]	GE Bing* (葛冰), ZANG Shu-sheng (臧述升), GUO Pei-qing (郭培卿). Experimental Study on Flow Structure of a Swirling Non-Premixed Syngas Flame[J]. 上海交通大学学报（英文版）, 2013, 18(1): 92-100.