Water wave diffraction by a cylinder array. Part 2. Irregular waves

C. O. G. OHL; P. H. TAYLOR; R. EATOCK TAYLOR; A. G. L. BORTHWICK

doi:10.1017/S0022112001004943

Abstract

Diffraction of irregular waves, focused wave groups, and random seas by an array of vertical bottom-mounted circular cylinders is investigated using theoretical, computational and experimental methods. This is an extension of our study of such an array in regular waves, reported in Part 1. Linear focused wave group theory is reviewed as a method for predicting the probable shape of extreme events from random wave spectra. Measurements are presented of the free surface elevation distribution in the vicinity of a multi-column structure in an offshore basin when subjected to irregular waves having peak frequencies and significant wave heights in the range 0.449 < kpa < 0.555 and 0.114 < Hs < 0.124 respectively, where a is the cylinder radius. Analytical linear diffraction theory is extended for application to focused wave groups and random seas. Experimental irregular wave data are analysed for comparison with this theory. Linear diffraction theory for random seas is shown to give an excellent prediction of incident wave spectral diffraction, while linear diffraction theory for focused wave groups works well for linearized extreme events. Due to the phase shifting of incident wave spectral components, diffraction is shown to generate focused wave groups in the vicinity of the cylinder array.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Silva, R. Govaere, G. and Salles, P. 2003. Wave interaction with cylindrical porous piles. Ocean Engineering, Vol. 30, Issue. 14, p. 1719.

Cai, Liang-Wu 2006. Evaluation of layered multiple-scattering method for antiplane shear wave scattering from gratings. The Journal of the Acoustical Society of America, Vol. 120, Issue. 1, p. 49.

Romolo, Alessandra and Arena, Felice 2008. Mechanics of nonlinear random wave groups interacting with a vertical wall. Physics of Fluids, Vol. 20, Issue. 3,

Jang, T. S. and Han, S. L. 2009. A numerical investigation of the inverse problem of the wavemaker. Ships and Offshore Structures, Vol. 4, Issue. 4, p. 315.

Liu, Shuxue Sun, Zhongbin and Li, Jinxuan 2012. An unstructured FEM model based on Boussinesq equations and its application to the calculation of multidirectional wave run-up in a cylinder group. Applied Mathematical Modelling, Vol. 36, Issue. 9, p. 4146.

Romolo, Alessandra and Arena, Felice 2012. NONLINEAR WAVE PRESSURES GIVEN BY EXTREME WAVES ON AN UPRIGHT BREAKWATER: THEORY AND EXPERIMENTAL VALIDATION. Coastal Engineering Proceedings, p. 33.

Grice, J.R. Taylor, P.H. and Eatock Taylor, R. 2013. Near-trapping effects for multi-column structures in deterministic and random waves. Ocean Engineering, Vol. 58, Issue. , p. 60.

Li, Jinxuan Wang, Zhanhang and Liu, Shuxue 2014. Experimental study of interactions between multi-directional focused wave and vertical circular cylinder, part II: Wave force. Coastal Engineering, Vol. 83, Issue. , p. 233.

Ji, Xinran Liu, Shuxue Bingham, Harry B. and Li, Jinxuan 2015. Multi-directional random wave interaction with an array of cylinders. Ocean Engineering, Vol. 110, Issue. , p. 62.

Cong, Peiwen Gou, Ying Teng, Bin Zhang, Kang and Huang, Yifan 2015. Model experiments on wave elevation around a four-cylinder structure. Ocean Engineering, Vol. 96, Issue. , p. 40.

Swan, C. and Sheikh, R. 2015. The interaction between steep waves and a surface-piercing column. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, Vol. 373, Issue. 2033, p. 20140114.

Aggarwal, Ankit Chella, Mayilvahanan Alagan Kamath, Arun Bihs, Hans and Arntsen, Øivind Asgeir 2016. Irregular Wave Forces on a Large Vertical Circular Cylinder. Energy Procedia, Vol. 94, Issue. , p. 504.

Aguilera, Laura Rosman, Paulo Cesar Colonna and Neves, Claudio Freitas 2020. Effects of an array of widely separated vertical cylinders on time-averaged properties of progressive monochromatic waves. RBRH, Vol. 25, Issue. ,

Lu, Wenyue Zhao, Wenhua Taylor, P.H. Yang, Jianmin Xiao, Longfei and Li, Xin 2020. Linearity and nonlinearity in wave run-up and air-gap response for a semi-submersible platform under irregular wave excitation. Applied Ocean Research, Vol. 104, Issue. , p. 102218.

Bernier, Carl Padgett, Jamie E. Lin, Yuxiang Dawson, Clint N. Lomonaco, Pedro and Cox, Daniel T. 2020. Laboratory Experiments of Vertical Cylinders Representative of Aboveground Storage Tanks Subjected to Waves. Journal of Structural Engineering, Vol. 146, Issue. 5,

Lin, Zaibin Pokrajac, Dubravka Guo, Yakun Liao, Chencong and Tang, Tian 2020. Near-trapping effect of wave-cylinders interaction on pore water pressure and liquefaction around a cylinder array. Ocean Engineering, Vol. 218, Issue. , p. 108047.

Zhang, Zhihao Tu, Jiahuang He, Yongkang Han, Zhaolong Yang, He Zhou, Dai and Fu, Shixiao 2021. The influence of regular wave and irregular wave on the mechanical characteristics of a triple-cylinder bundle structure. Ocean Engineering, Vol. 220, Issue. , p. 108379.

Ding, Yue Taylor, Paul H. Zhao, Wenhua Dory, Jean-Noel Hlophe, Thobani and Draper, Scott 2023. Oceanographic wave buoy motion as a 3D-vector field: Spectra, linear components and bound harmonics. Applied Ocean Research, Vol. 141, Issue. , p. 103777.

Konispoliatis, Dimitrios N. 2023. Near trapping phenomena in arrays of porous vertical cylinders. Physics of Fluids, Vol. 35, Issue. 9,

Cong, Peiwen Zhao, Mingqiang Teng, Bin Gou, Ying and Liu, Yingyi 2023. Second-order near trapping of water waves by a square array of vertical columns in bi-chromatic seas. Journal of Fluids and Structures, Vol. 121, Issue. , p. 103916.

Download full list

Article contents

Water wave diffraction by a cylinder array. Part 2. Irregular waves

Abstract

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Water wave diffraction by a cylinder array. Part 2. Irregular waves

Abstract

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests